TW201804670A - Antenna structure and wireless communication device with same - Google Patents

Antenna structure and wireless communication device with same Download PDF

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TW201804670A
TW201804670A TW106121492A TW106121492A TW201804670A TW 201804670 A TW201804670 A TW 201804670A TW 106121492 A TW106121492 A TW 106121492A TW 106121492 A TW106121492 A TW 106121492A TW 201804670 A TW201804670 A TW 201804670A
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Taiwan
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branch
antenna structure
frequency band
electrically connected
frequency
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TW106121492A
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Chinese (zh)
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TWI656688B (en
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李承翰
許溢文
葉維軒
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群邁通訊股份有限公司
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Priority to US15/651,035 priority Critical patent/US10020562B2/en
Priority to EP17182065.7A priority patent/EP3273533B1/en
Publication of TW201804670A publication Critical patent/TW201804670A/en
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Publication of TWI656688B publication Critical patent/TWI656688B/en

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Abstract

The present invention provides an antenna structure including a housing, a first feed source, and a first switching circuit. The housing includes a front frame, a backboard, and a side frame. The side frame defines a slot. The front frame defines a first gap and a second gap. The housing is divided into a first branch and a second branch by the slot, the first gap, and the second gap. The second branch is grounded. The first feed source is electrically connected to the first branch. One end of the first switching circuit is electrically connected to the first branch. Another end of the first switching circuit is grounded.

Description

天線結構及具有該天線結構之無線通訊裝置Antenna structure and wireless communication device having the same

本發明涉及一種天線結構及具有該天線結構之無線通訊裝置。The invention relates to an antenna structure and a wireless communication device having the same.

隨著無線通訊技術之進步,無線通訊裝置不斷朝向輕薄趨勢發展,消費者對於產品外觀之要求亦越來越高。由於金屬殼體於外觀、機構強度、散熱效果等方面具有優勢,因此越來越多之廠商設計出具有金屬殼體,例如金屬背板之無線通訊裝置來滿足消費者之需求。然,金屬殼體容易干擾遮蔽設置於其內之天線所輻射之訊號,不容易達到寬頻設計,導致內置天線之輻射性能不佳。再者,所述背板上通常還設置有開槽及斷點,如此將影響背板之完整性與美觀性。With the advancement of wireless communication technology, wireless communication devices are constantly moving toward a thin and light trend, and consumers are increasingly demanding the appearance of products. Due to the advantages of the metal casing in terms of appearance, mechanism strength, heat dissipation effect, etc., more and more manufacturers have designed wireless communication devices with metal casings, such as metal back plates, to meet the needs of consumers. However, the metal casing easily interferes with the signal radiated by the antenna disposed therein, and the broadband design is not easily achieved, resulting in poor radiation performance of the built-in antenna. Moreover, the backing plate is usually provided with a slot and a break point, which will affect the integrity and aesthetics of the backboard.

有鑑於此,有必要提供一種天線結構及具有該天線結構之無線通訊裝置。In view of the above, it is necessary to provide an antenna structure and a wireless communication device having the same.

一種天線結構,包括殼體、第一饋入源以及第一切換電路,所述殼體包括前框、背板以及邊框,所述邊框夾設於所述前框與所述背板之間,所述邊框上開設有開槽,所述前框上開設有第一斷點及第二斷點,所述第一斷點與所述開槽之第一末端連通並延伸至隔斷所述前框,所述第二斷點設置於所述第一斷點與所述開槽之第二末端之間並延伸至隔斷所述前框,所述開槽、所述第一斷點及所述第二斷點共同自所述殼體劃分出第一分支及第二分支,所述第一斷點與所述第二斷點之間之所述前框構成所述第一分支,所述第二斷點與所述第二末端之間之所述前框構成所述第二分支,所述第二分支於所述第二末端之位置接地,所述第一饋入源電連接至所述第一分支,所述第一切換電路之一端電連接至所述第一分支,另一端接地。An antenna structure includes a housing, a first feeding source, and a first switching circuit, the housing includes a front frame, a backboard, and a frame, and the frame is sandwiched between the front frame and the backboard. a slot is formed in the frame, the first frame is open with a first break point and a second break point, and the first break point is connected to the first end of the slot and extends to block the front frame The second break point is disposed between the first break point and the second end of the slot and extends to block the front frame, the slot, the first break point, and the first The two break points jointly divide the first branch and the second branch from the housing, and the front frame between the first break point and the second break point constitutes the first branch, and the second The front frame between the break point and the second end constitutes the second branch, the second branch is grounded at the position of the second end, and the first feed source is electrically connected to the first A branch, one end of the first switching circuit is electrically connected to the first branch, and the other end is grounded.

一種無線通訊裝置,包括上述項所述之天線結構。A wireless communication device comprising the antenna structure described in the above item.

上述天線結構及具有該天線結構之無線通訊裝置可涵蓋至低、中、高頻,頻率範圍較廣。另外,該天線結構之殼體上之開槽、第一斷點及第二斷點均設置於所述前框及邊框上,並未設置於所述背板上,使得所述背板構成全金屬結構,即所述背板上並沒有絕緣之開槽、斷線或斷點,使得所述背板可避免由於開槽、斷線或斷點之設置而影響背板之完整性與美觀性。The above antenna structure and the wireless communication device having the antenna structure can cover low, medium and high frequency, and have a wide frequency range. In addition, the slot, the first break point, and the second break point on the housing of the antenna structure are disposed on the front frame and the frame, and are not disposed on the back board, so that the back board forms a complete The metal structure, that is, the slot, disconnection or break point without insulation on the back plate, so that the back plate can avoid the integrity and aesthetics of the back plate due to the setting of slotting, disconnection or breakpoint .

下面將結合本發明實施例中之附圖,對本發明實施例中之技術方案進行清楚、完整地描述,顯然,所描述之實施例僅僅是本發明一部分實施例,而不是全部之實施例。基於本發明中之實施例,所屬領域具有通常知識者於沒有做出創造性勞動前提下所獲得之所有其他實施例,均屬於本發明保護之範圍。The technical solutions in the embodiments of the present invention are clearly and completely described in the following with reference to the accompanying drawings in the embodiments of the present invention. It is obvious that the described embodiments are only a part of the embodiments of the present invention, but not all embodiments. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present invention without the creative work are all within the scope of the present invention.

需要說明之是,當一個元件被稱為“電連接”另一個元件,它可直接於另一個元件上或者亦可存在居中之元件。當一個元件被認為是“電連接”另一個元件,它可是接觸連接,例如,可是導線連接之方式,亦可是非接觸式連接,例如,可是非接觸式耦合之方式。It should be noted that when an element is referred to as "electrically connected" to another element, it can be directly on the other element or the element can be present. When an element is considered to be "electrically connected" to another element, it can be a contact connection, for example, a wire connection or a non-contact connection, for example, a non-contact coupling.

除非另有定義,本文所使用之所有之技術與科學術語與屬於所屬領域具有通常知識者通常理解之含義相同。本文中於本發明之說明書中所使用之術語僅是為描述具體之實施例之目不是旨在於限制本發明。本文所使用之術語“及/或”包括一個或多個相關之所列項目的任意之與所有之組合。Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art. The terminology used in the description of the invention herein is for the purpose of describing the particular embodiments. The term "and/or" used herein includes any and all combinations of one or more of the associated listed items.

下面結合附圖,對本發明之一些實施方式作詳細說明。於不衝突之情況下,下述之實施例及實施例中之特徵可相互組合。Some embodiments of the present invention are described in detail below with reference to the accompanying drawings. The features of the embodiments and examples described below may be combined with each other without conflict.

實施例1Example 1

請參閱圖1,本發明較佳實施方式提供一種天線結構100,其可應用於行動電話、個人數位助理等無線通訊裝置400中,用以發射、接收無線電波以傳遞、交換無線訊號。Referring to FIG. 1, a preferred embodiment of the present invention provides an antenna structure 100 that can be applied to a wireless communication device 400 such as a mobile phone or a personal digital assistant to transmit and receive radio waves to transmit and exchange wireless signals.

請一併參閱圖2及圖3,所述天線結構100包括殼體11、第一饋入源13、第二饋入源15、第一匹配電路16、第二匹配電路17、連接部18以及切換電路19。所述殼體11可為所述無線通訊裝置400之外殼。於本實施例中,所述殼體11由金屬材料製成。所述殼體11包括前框111、背板112及邊框113。所述前框111、背板112及邊框113可是一體成型。所述前框111、背板112以及邊框113構成所述無線通訊裝置400之外殼。所述前框111上設置有一開口(圖未標),用於容置所述無線通訊裝置400之顯示單元401。可理解,所述顯示單元401具有一顯示平面,該顯示平面裸露於該開口,且該顯示平面與所述背板112大致平行設置。Referring to FIG. 2 and FIG. 3 together, the antenna structure 100 includes a housing 11 , a first feed source 13 , a second feed source 15 , a first matching circuit 16 , a second matching circuit 17 , a connecting portion 18 , and Switching circuit 19. The housing 11 can be an outer casing of the wireless communication device 400. In the present embodiment, the housing 11 is made of a metal material. The housing 11 includes a front frame 111, a back plate 112, and a frame 113. The front frame 111, the back plate 112 and the frame 113 may be integrally formed. The front frame 111, the back plate 112 and the frame 113 constitute an outer casing of the wireless communication device 400. An opening (not labeled) is disposed on the front frame 111 for receiving the display unit 401 of the wireless communication device 400. It can be understood that the display unit 401 has a display plane, the display plane is exposed to the opening, and the display plane is disposed substantially parallel to the backboard 112.

請一併參閱圖4,所述背板112與所述前框111相對設置。所述背板112與邊框113直接連接,所述背板112與邊框113之間沒有空隙。所述背板112為一體成型之單一金屬片,為顯露相機鏡頭402與閃光燈403等元件,所述背板112設置開孔404、405。所述背板112其上並沒有設置任何用於分割所述背板112之絕緣之開槽、斷線或斷點。所述背板112可作為所述天線結構100之地。Referring to FIG. 4 together, the back plate 112 is disposed opposite to the front frame 111. The back plate 112 is directly connected to the frame 113, and there is no gap between the back plate 112 and the frame 113. The back plate 112 is an integrally formed single metal piece for exposing components such as the camera lens 402 and the flash 403. The back plate 112 is provided with openings 404 and 405. The backing plate 112 is not provided with any slot, break or break point for separating the insulation of the backing plate 112. The backing plate 112 can serve as the ground for the antenna structure 100.

所述邊框113夾設於所述前框111與所述背板112之間,且分別環繞所述前框111及所述背板112之周緣設置,以與所述顯示單元401、所述前框111以及背板112共同圍成一容置空間114。所述容置空間114用以容置所述無線通訊裝置400之電路板、處理單元等電子元件或電路模組於其內。The frame 113 is disposed between the front frame 111 and the back plate 112, and is disposed around the periphery of the front frame 111 and the back plate 112 to be opposite to the display unit 401 and the front The frame 111 and the back plate 112 together form an accommodation space 114. The accommodating space 114 is configured to receive electronic components or circuit modules of the circuit board, the processing unit, and the like of the wireless communication device 400.

所述邊框113至少包括末端部115、第一側部116以及第二側部117。於本實施例中,所述末端部115為所述無線通訊裝置400之頂端。所述末端部115連接所述前框111與所述背板112。所述第一側部116與所述第二側部117相對設置,兩者分別設置於所述末端部115之兩端,優選垂直設置。所述第一側部116與所述第二側部117亦連接所述前框111與所述背板112。The frame 113 includes at least a tip portion 115, a first side portion 116, and a second side portion 117. In the embodiment, the end portion 115 is the top end of the wireless communication device 400. The end portion 115 connects the front frame 111 and the back plate 112. The first side portion 116 is disposed opposite to the second side portion 117, and is disposed at two ends of the end portion 115, preferably vertically. The first side portion 116 and the second side portion 117 are also connected to the front frame 111 and the back plate 112.

所述邊框113上還開設有開槽118,所述前框111上開設有斷點119及縫隙120。於本實施例中,所述開槽118佈設於所述末端部115上,並且分別延伸至所述第一側部116及第二側部117。可理解,於其他實施例中,所述開槽118亦可僅設置於所述末端部115,而未延伸至所述第一側部116及第二側部117中之任何一個,或者所述開槽118設置於所述末端部115,且僅沿延伸至所述第一側部116及第二側部117中之其中之一。The frame 113 is further provided with a slot 118, and the front frame 111 is provided with a break point 119 and a slot 120. In the embodiment, the slots 118 are disposed on the end portion 115 and extend to the first side portion 116 and the second side portion 117, respectively. It can be understood that in other embodiments, the slot 118 may be disposed only in the end portion 115 without extending to any one of the first side portion 116 and the second side portion 117, or A slot 118 is provided in the end portion 115 and extends only to one of the first side portion 116 and the second side portion 117.

所述斷點119與所述開槽118連通,並延伸至隔斷所述前框111。於本實施例中,所述斷點119鄰近所述第一側部116設置,如此所述斷點119將對應所述開槽118之所述前框111劃分為兩部分,即第一輻射部A1及第二輻射部A2。其中,所述斷點119一側之前框111直至其延伸至與所述開槽118之第一末端E1相對應之部分共同形成所述第一輻射部A1。所述斷點119另一側之前框111直至其延伸至與所述開槽118之第二末端E2相對應之部分形成所述第二輻射部A2。於本實施例中,所述斷點119開設之位置並非對應到所述末端部115之中間,因此所述第一輻射部A1之長度小於第二輻射部A2之長度。The break point 119 is in communication with the slot 118 and extends to block the front frame 111. In the present embodiment, the break point 119 is disposed adjacent to the first side portion 116, such that the break point 119 divides the front frame 111 corresponding to the slot 118 into two parts, that is, the first radiating portion. A1 and second radiation portion A2. Wherein, the front frame 111 of the break point 119 side is extended to a portion corresponding to the first end E1 of the slot 118 to form the first radiating portion A1. The other side of the break point 119 is preceded by the frame 111 until it extends to a portion corresponding to the second end E2 of the slot 118 to form the second radiating portion A2. In this embodiment, the position where the break point 119 is opened does not correspond to the middle of the end portion 115, so the length of the first radiating portion A1 is smaller than the length of the second radiating portion A2.

所述縫隙120與所述開槽118連通,並延伸至隔斷所述前框111。於本實施例中,所述縫隙120鄰近所述第二側部117設置,如此所述縫隙120將所述第二輻射部A2進一步劃分出兩部分,即第一分支B1及第二分支B2。其中,所述斷點119與縫隙120之間之前框111形成所述第一分支B1。所述縫隙120遠離所述斷點119一側之前框111直至其延伸至與所述開槽118之第二末端E2相對應之部分共同形成所述第二分支B2。於本實施例中,所述縫隙120開設之位置並非對應到所述第二輻射部A2之中間,因此所述第一分支B1之長度大於所述第二分支B2之長度。另外,所述第一輻射部A1之長度小於所述第二分支B2之長度。The slit 120 is in communication with the slot 118 and extends to block the front frame 111. In the embodiment, the slit 120 is disposed adjacent to the second side portion 117, such that the slit 120 further divides the second radiating portion A2 into two parts, that is, the first branch B1 and the second branch B2. Wherein, the front frame 111 between the break point 119 and the slit 120 forms the first branch B1. The slit 120 is away from the front frame 111 of the break point 119 until it extends to a portion corresponding to the second end E2 of the slot 118 to form the second branch B2. In this embodiment, the position where the slit 120 is opened does not correspond to the middle of the second radiating portion A2, so the length of the first branch B1 is greater than the length of the second branch B2. In addition, the length of the first radiating portion A1 is smaller than the length of the second branch B2.

於本實施例中,所述開槽118、所述斷點119及所述縫隙120內均填充有絕緣材料(例如塑膠、橡膠、玻璃、木材、陶瓷等,但不以此為限),進而區隔所述第一輻射部A1、第二輻射部A2之第一分支B1及第二分支B2與所述殼體11之其餘部分。In this embodiment, the slot 118, the break point 119, and the slot 120 are filled with an insulating material (for example, plastic, rubber, glass, wood, ceramic, etc., but not limited thereto), and further The first branch B1 and the second branch B2 of the first radiating portion A1 and the second radiating portion A2 are separated from the rest of the casing 11.

可理解,於本實施例中,所述開槽118開設於所述邊框113靠近所述背板112之一端,並延伸至所述前框111,以使得所述第一輻射部A1、第二輻射部A2之第一分支B1及第二分支B2完全由部分所述前框111構成。當然,於其他實施例中,所述開槽118之開設位置亦可根據具體需求進行調整。例如,所述開槽118開設於所述邊框113靠近所述背板112之一端,並朝所述前框111所在方向延伸,以使得所述第一輻射部A1、第二輻射部A2之第一分支B1及第二分支B2由部分所述前框111及部分所述邊框113構成。It can be understood that, in this embodiment, the slot 118 is opened at one end of the frame 113 near the back plate 112 and extends to the front frame 111 to make the first radiating portion A1 and the second portion The first branch B1 and the second branch B2 of the radiation portion A2 are completely constituted by a part of the front frame 111. Of course, in other embodiments, the opening position of the slot 118 can also be adjusted according to specific needs. For example, the slot 118 is opened at one end of the frame 113 near the back plate 112 and extends toward the front frame 111 so that the first radiating portion A1 and the second radiating portion A2 are A branch B1 and a second branch B2 are composed of a part of the front frame 111 and a part of the frame 113.

可理解,所述前框111與邊框113之上半部除了所述開槽118、斷點119及縫隙120以外沒有再設置其他絕緣之開槽、斷線或斷點,因此所述前框111之上半部就僅有斷點119及縫隙120,沒有其他斷點。It can be understood that the front frame 111 and the upper half of the frame 113 are not provided with other insulating slots, broken lines or break points except the slot 118, the break point 119 and the slot 120, so the front frame 111 In the upper half, there are only breakpoints 119 and slots 120, and there are no other breakpoints.

所述第一饋入源13設置於所述容置空間114內,且鄰近所述開槽118之第二末端E2設置。所述第一饋入源13之一端藉由所述第一匹配電路16及連接部18分別電連接至所述第一分支B1及第二分支B2,進而分別為所述第一分支B1及第二分支B2饋入電流,以使得所述第一分支B1激發一第一模態以產生第一頻段之輻射訊號,所述第二分支B2激發一第二模態以產生第二頻段之輻射訊號。於本實施例中,所述第一模態為低頻模態,所述第一頻段為LTE-A 734-960MHz頻段。所述第二模態為中頻模態,所述第二頻段為LTE-A 1805-2170頻段。The first feed source 13 is disposed in the accommodating space 114 and disposed adjacent to the second end E2 of the slot 118. One end of the first feed source 13 is electrically connected to the first branch B1 and the second branch B2 by the first matching circuit 16 and the connecting portion 18, respectively, and is respectively the first branch B1 and the first branch The second branch B2 feeds current such that the first branch B1 excites a first mode to generate a radiation signal of a first frequency band, and the second branch B2 excites a second mode to generate a radiation signal of a second frequency band . In this embodiment, the first mode is a low frequency mode, and the first frequency band is an LTE-A 734-960 MHz frequency band. The second mode is an intermediate frequency mode, and the second frequency band is an LTE-A 1805-2170 frequency band.

於本實施例中,所述連接部18包括第一連接段181、第二連接段183、第三連接段185及第四連接段187。所述第一連接段181、第二連接段183、第三連接段185及第四連接段187共面設置。所述第一連接段181大致呈矩形條狀,其一端藉由所述第一匹配電路16連接至所述第一饋入源13,另一端沿平行所述末端部115且靠近所述第一側部116之方向延伸。所述第二連接段183大致呈矩形條狀,其一端垂直連接至所述第一連接段181遠離所述第一饋入源13之一端,另一端沿平行所述第一側部116且靠近所述末端部115之方向延伸,直至與所述第一分支B1鄰近所述縫隙120之部分連接,進而饋入電流至所述第一分支B1。In the embodiment, the connecting portion 18 includes a first connecting portion 181, a second connecting portion 183, a third connecting portion 185, and a fourth connecting portion 187. The first connecting section 181, the second connecting section 183, the third connecting section 185 and the fourth connecting section 187 are disposed in a coplanar manner. The first connecting section 181 has a substantially rectangular strip shape, one end of which is connected to the first feeding source 13 by the first matching circuit 16, and the other end is parallel to the end portion 115 and close to the first The direction of the side portion 116 extends. The second connecting portion 183 has a substantially rectangular strip shape, and one end thereof is perpendicularly connected to the first connecting portion 181 away from one end of the first feeding source 13 and the other end is parallel to the first side portion 116 and close to The end portion 115 extends in a direction until it is connected to a portion of the first branch B1 adjacent to the slit 120, thereby feeding current to the first branch B1.

所述第三連接段185大致呈矩形條狀,其一端連接至所述第一連接段181與所述第一饋入源13之連接處,另一端沿平行所述第二連接段183且遠離所述末端部115之方向延伸。所述第四連接段187大致呈矩形條狀,其一端垂直連接至所述第三連接段185遠離所述第一饋入源13之一端,另一端沿平行所述第一連接段181且靠近所述第二側部117之方向延伸,直至與所述第二分支B2鄰近所述第二末端E2之部分連接,進而饋入電流至所述第二分支B2。The third connecting section 185 has a substantially rectangular strip shape, one end of which is connected to the connection of the first connecting section 181 and the first feeding source 13 , and the other end is parallel to the second connecting section 183 and away from The end portion 115 extends in the direction. The fourth connecting section 187 has a substantially rectangular strip shape, one end of which is perpendicularly connected to the third connecting section 185 away from one end of the first feeding source 13 and the other end is parallel to the first connecting section 181 and close to The second side portion 117 extends in a direction until it is connected to a portion of the second branch B2 adjacent to the second end E2, thereby feeding current to the second branch B2.

於本實施例中,所述第二饋入源15設置於所述容置空間114內,且鄰近所述開槽118之第一末端E1設置。所述第二饋入源15之一端藉由所述第二匹配電路17與所述第一輻射部A1電連接,另一端電連接至所述背板112,進而為所述第一輻射部A1饋入電流,使得所述第一輻射部A1激發一第三模態以產生第三頻段之輻射訊號。本實施例中,所述第三模態為一高頻模態,所述第三頻段為LTE-A 2300-2400MHz、LTE-A 2496-2690MHz及WIFI 2.4 GHz頻段。In this embodiment, the second feed source 15 is disposed in the accommodating space 114 and disposed adjacent to the first end E1 of the slot 118. One end of the second feed source 15 is electrically connected to the first radiating portion A1 by the second matching circuit 17, and the other end is electrically connected to the back plate 112, and further to the first radiating portion A1. The current is fed such that the first radiating portion A1 excites a third mode to generate a radiation signal of the third frequency band. In this embodiment, the third mode is a high frequency mode, and the third frequency band is an LTE-A 2300-2400 MHz, an LTE-A 2496-2690 MHz, and a WIFI 2.4 GHz band.

請一併參閱圖5,所述切換電路19之一端電連接至所述第一分支B1靠近所述第二連接段183之位置,另一端電連接至所述背板112,即接地。所述切換電路19包括切換單元191及至少一切換元件193。所述切換單元191電連接至所述第一分支B1。所述切換元件193可為電感、電容、或者電感與電容之組合。所述切換元件193之間相互並聯,且其一端電連接至所述切換單元191,另一端電連接至背板112,即接地。如此,藉由控制所述切換單元191之切換,可使得所述第一分支B1切換至不同之切換元件193。由於每一個切換元件193具有不同之阻抗,因此藉由所述切換單元191之切換,可有效調整所述第一分支B1之第一模態之頻段。Referring to FIG. 5 together, one end of the switching circuit 19 is electrically connected to a position where the first branch B1 is close to the second connecting segment 183, and the other end is electrically connected to the backing plate 112, that is, grounded. The switching circuit 19 includes a switching unit 191 and at least one switching element 193. The switching unit 191 is electrically connected to the first branch B1. The switching element 193 can be an inductor, a capacitor, or a combination of an inductor and a capacitor. The switching elements 193 are connected in parallel with each other, and one end thereof is electrically connected to the switching unit 191, and the other end is electrically connected to the backing plate 112, that is, grounded. Thus, by controlling the switching of the switching unit 191, the first branch B1 can be switched to a different switching element 193. Since each of the switching elements 193 has a different impedance, the frequency band of the first mode of the first branch B1 can be effectively adjusted by the switching of the switching unit 191.

可理解,於本實施例中,所述第一分支B1還可額外激發一第四模態以產生第四頻段之輻射訊號。具體請一併參閱圖6及圖7,所述切換電路19還可包括諧振電路195。請參閱圖6,於其中一實施例中,所述諧振電路195之數量為一個,所述諧振電路195包括相互串聯之電感L及電容C。所述諧振電路195電連接於所述第一分支B1及背板112之間,且與所述切換單元191及至少一切換元件193並聯設置。It can be understood that, in this embodiment, the first branch B1 may additionally excite a fourth mode to generate a radiation signal of the fourth frequency band. For details, please refer to FIG. 6 and FIG. 7 , the switching circuit 19 may further include a resonant circuit 195 . Referring to FIG. 6, in one embodiment, the number of the resonant circuits 195 is one, and the resonant circuit 195 includes an inductor L and a capacitor C connected in series. The resonant circuit 195 is electrically connected between the first branch B1 and the back plate 112, and is disposed in parallel with the switching unit 191 and the at least one switching element 193.

請參閱圖7,於另外一實施例中,所述諧振電路195之數量與所述切換元件193之數量一致,即為多個。每一諧振電路195包括相互串聯之電感L1-Ln及電容C1-Cn。每一個所述諧振電路195分別電連接於所述切換單元191及背板112之間,並與對應之切換元件193並聯設置。Referring to FIG. 7, in another embodiment, the number of the resonant circuits 195 is the same as the number of the switching elements 193, that is, multiple. Each of the resonant circuits 195 includes inductors L1-Ln and capacitors C1-Cn connected in series with each other. Each of the resonant circuits 195 is electrically connected between the switching unit 191 and the backplane 112, and is disposed in parallel with the corresponding switching component 193.

可理解,所述背板112可作為所述天線結構100與所述無線通訊裝置400之地。於另一實施例中,於所述顯示單元401朝向所述背板112那一面可設置用於屏蔽電磁干擾之屏蔽罩(shielding mask)或支撐所述顯示單元401之中框。所述屏蔽罩或中框以金屬材料製作。所述屏蔽罩或中框可與所述背板112相連接以作為所述天線結構100與所述無線通訊裝置400之地。於圖5-7中,所述屏蔽罩或中框可取代所述背板112以供所述切換電路19接地。It can be understood that the backplane 112 can serve as the antenna structure 100 and the wireless communication device 400. In another embodiment, a shielding mask for shielding electromagnetic interference or supporting a frame in the display unit 401 may be disposed on a side of the display unit 401 facing the backboard 112. The shield or the middle frame is made of a metal material. The shield or middle frame may be coupled to the back plate 112 to serve as the ground structure 100 and the wireless communication device 400. In FIGS. 5-7, the shield or middle frame can replace the backing plate 112 for grounding the switching circuit 19.

圖8為於圖6所示所述切換電路19並聯一個諧振電路195,且所述諧振電路195包括相互串聯之電感L及電容C時,所述第二輻射部A2之S參數(散射參數)與頻率之間之關係原理圖。其中,假設當所述切換電路19未增加圖6所示所述諧振電路195時,所述天線結構100之第一分支B1工作於第一模態(請參曲線S81)。當所述切換電路19增加所述諧振電路195時,所述諧振電路195可使得所述第一分支B1額外共振出一窄頻模態,即第四模態(請參曲線S82),以產生第四頻段之輻射訊號,即可有效增加所述天線結構100之應用頻段,達到多頻或寬頻應用。於一實施例中,所述第四頻段可是GPS頻段,所述第四模態亦就是GPS諧振模態。8 is a parallel circuit 195 of the switching circuit 19 shown in FIG. 6, and the S circuit (scattering parameter) of the second radiating portion A2 when the resonant circuit 195 includes an inductor L and a capacitor C connected in series with each other. Schematic diagram of the relationship between frequency and frequency. It is assumed that when the switching circuit 19 does not increase the resonant circuit 195 shown in FIG. 6, the first branch B1 of the antenna structure 100 operates in the first mode (refer to curve S81). When the switching circuit 19 increases the resonant circuit 195, the resonant circuit 195 may cause the first branch B1 to additionally resonate to a narrow frequency mode, that is, a fourth mode (refer to curve S82) to generate The radiation signal of the fourth frequency band can effectively increase the application frequency band of the antenna structure 100 to achieve multi-frequency or broadband application. In an embodiment, the fourth frequency band may be a GPS frequency band, and the fourth mode is also a GPS resonant mode.

圖9為於圖7所示所述切換電路19中每一切換元件193一側並聯一個諧振電路195,且所述諧振電路195包括相互串聯之電感L1-Ln及電容C1-Cn時,所述第二輻射部A2之S參數(散射參數)與頻率之間之關係原理圖。其中,假設當所述切換電路19未增加圖7所示所述諧振電路195時,所述天線結構100之第一分支B1工作於第一模態(請參曲線S91)。如此當所述切換電路19增加所述諧振電路195時,所述諧振電路195可使得所述第一分支B1額外共振出所述窄頻模態(請參曲線S92),亦就是GPS共振模態,即可有效增加所述天線結構100之應用頻段,達到多頻或寬頻應用。另外,藉由設置所述諧振電路195中電感L1-Ln之電感值與所述電容C1-Cn之電容值,可決定所述第一模態切換時所述窄頻模態之頻段。例如,於其中一個實施例中,例如圖9所示,可藉由設置所述諧振電路195中之電感值與電容值,使切換單元191切換至不同之切換元件193時,所述天線結構100之窄頻模態(即第四模態)亦隨之切換,例如可由f1移動至fn,移動範圍十分廣泛。9 is a resonant circuit 195 connected in parallel with each switching element 193 side of the switching circuit 19 shown in FIG. 7, and the resonant circuit 195 includes inductors L1-Ln and capacitors C1-Cn connected in series with each other. Schematic diagram of the relationship between the S parameter (scattering parameter) of the second radiating portion A2 and the frequency. It is assumed that when the switching circuit 19 does not increase the resonant circuit 195 shown in FIG. 7, the first branch B1 of the antenna structure 100 operates in the first mode (refer to curve S91). Thus, when the switching circuit 19 increases the resonant circuit 195, the resonant circuit 195 can cause the first branch B1 to additionally resonate out of the narrowband mode (see curve S92), that is, the GPS resonant mode. The application frequency band of the antenna structure 100 can be effectively increased to achieve multi-frequency or broadband applications. In addition, by setting the inductance value of the inductance L1-Ln in the resonant circuit 195 and the capacitance value of the capacitance C1-Cn, the frequency band of the narrow-band mode at the first mode switching can be determined. For example, in one embodiment, as shown in FIG. 9, the antenna structure 100 can be switched when the switching unit 191 is switched to a different switching element 193 by setting the inductance value and the capacitance value in the resonant circuit 195. The narrow-band mode (ie, the fourth mode) is also switched, for example, from f1 to fn, and the range of motion is very wide.

可理解,於另一實施例中,還可藉由設置所述諧振電路195中之電感值與電容值而固定所述窄頻模態之頻段,從而使所述切換單元191無論切換至哪一個切換元件193,所述窄頻模態之頻段均固定不動。It can be understood that, in another embodiment, the frequency band of the narrowband mode can be fixed by setting the inductance value and the capacitance value in the resonant circuit 195, so that the switching unit 191 switches to which one. The switching element 193 has a fixed frequency band of the narrow frequency mode.

可理解,於其他實施例中,所述諧振電路195不局限於包括所述電感L及電容C,其還可由其他之諧振元件組成。例如,請一併參閱圖10及圖11,於另外一實施例中,所述諧振電路195僅包括電容C或電容C1-Cn。如此,請參閱圖12,為電壓駐波比(standing wave ratio,SWR)與頻率之關係示意圖。當改變所述電容C或電容C1-Cn之電容值時,可有效移動所述窄頻模態f1之倍頻模態fh,應用範圍十分廣泛。It can be understood that in other embodiments, the resonant circuit 195 is not limited to include the inductor L and the capacitor C, and may also be composed of other resonant components. For example, please refer to FIG. 10 and FIG. 11 together. In another embodiment, the resonant circuit 195 includes only the capacitor C or the capacitors C1-Cn. So, please refer to Figure 12, which is a schematic diagram of the relationship between the standing wave ratio (SWR) and the frequency. When the capacitance value of the capacitor C or the capacitor C1-Cn is changed, the frequency doubling mode fh of the narrow frequency mode f1 can be effectively moved, and the application range is very wide.

圖13為所述天線結構100之電流走向示意圖。顯然,當電流自所述第一饋入源13饋入後,一部分電流將經所述連接部18流入所述第二輻射部A2之第一分支B1,並流向所述斷點119(參路徑P1),進而激發出所述第一模態以產生第一頻段之輻射訊號。當電流自所述第一饋入源13饋入後,另外一部分電流將經所述連接部18流入所述第二輻射部A2之第二分支B2,並流向所述縫隙120(參路徑P2),進而激發出所述第二模態以產生第二頻段之輻射訊號。當電流自所述第二饋入源15進入後,將流經所述第一輻射部A1,並流向所述斷點119(參路徑P3),進而激發出所述第三模態以產生第三頻段之輻射訊號。FIG. 13 is a schematic diagram of current flow of the antenna structure 100. Obviously, when a current is fed from the first feed source 13, a portion of the current will flow into the first branch B1 of the second radiating portion A2 via the connecting portion 18, and flow to the break point 119 (the path) P1), thereby exciting the first mode to generate a radiation signal of the first frequency band. After the current is fed from the first feed source 13, another portion of the current will flow into the second branch B2 of the second radiating portion A2 via the connecting portion 18 and flow to the slit 120 (refer to the path P2). And exciting the second mode to generate a radiation signal of the second frequency band. When the current enters from the second feed source 15, it will flow through the first radiation portion A1 and flow to the break point 119 (refer to the path P3), thereby exciting the third mode to generate the first Three-band radiation signal.

可理解,由於所述天線結構100設置有切換電路19,因此可利用所述切換電路19之切換,進而切換所述第一頻段,同時不影響中、高頻之操作。再者,由於所述切換電路19設置有所述諧振電路195。如此,可使得電流自所述切換電路19流向所述斷點119(參路徑P4),以使得所述第一分支B1搭配所述諧振電路195而激發出所述第四模態以產生第四頻段之輻射訊號。It can be understood that, since the antenna structure 100 is provided with the switching circuit 19, the switching of the switching circuit 19 can be utilized to switch the first frequency band without affecting the operation of the medium and high frequencies. Furthermore, since the switching circuit 19 is provided with the resonant circuit 195. In this way, current can flow from the switching circuit 19 to the breakpoint 119 (refer to the path P4), so that the first branch B1 is coupled with the resonant circuit 195 to excite the fourth mode to generate a fourth Radiation signal in the frequency band.

圖14為所述天線結構100工作於低頻模態、GPS模態以及中頻模態時之S參數(散射參數)曲線圖。其中,曲線S141為所述天線結構100工作於LTE-A 734-756MHz時之S11值。曲線S142為所述天線結構100工作於LTE-A 791-821MHz時之S11值。曲線S143為所述天線結構100工作於LTE-A 869-894MHz時之S11值。曲線S144為所述天線結構100工作於LTE-A 925-960MHz時之S11值。曲線S145為所述天線結構100工作於1575MHz時之S11值。曲線S146為所述天線結構100工作於LTE-A 1805-2170MHz時之S11值。顯然,曲線S141-S144分別對應四個不同頻段,並分別對應所述切換電路19可切換之多個低頻模態之其中四個。14 is a graph of S-parameters (scattering parameters) of the antenna structure 100 when operating in a low frequency mode, a GPS mode, and an intermediate frequency mode. The curve S141 is the S11 value when the antenna structure 100 operates at LTE-A 734-756 MHz. Curve S142 is the S11 value when the antenna structure 100 operates at LTE-A 791-821 MHz. Curve S143 is the S11 value when the antenna structure 100 operates at LTE-A 869-894 MHz. Curve S144 is the S11 value when the antenna structure 100 operates at LTE-A 925-960 MHz. Curve S145 is the S11 value at which the antenna structure 100 operates at 1575 MHz. Curve S146 is the S11 value when the antenna structure 100 operates at LTE-A 1805-2170 MHz. Obviously, the curves S141-S144 respectively correspond to four different frequency bands, and respectively correspond to four of the plurality of low frequency modes that the switching circuit 19 can switch.

圖15為所述天線結構100工作於低頻模態、GPS模態以及中頻模態時之總輻射效率圖。其中,曲線S151為所述天線結構100工作於LTE-A 734-756MHz時之總輻射效率。曲線S152為所述天線結構100工作於LTE-A 791-821MHz時之總輻射效率。曲線S153為所述天線結構100工作於LTE-A 869-894MHz時之總輻射效率。曲線S154為所述天線結構100工作於LTE-A 925-960MHz時之總輻射效率。曲線S155為所述天線結構100工作於1575MHz時之總輻射效率。曲線S156為所述天線結構100工作於LTE-A 1805-2170MHz時之總輻射效率。顯然,曲線S151-S154分別對應四個不同頻段,並分別對應所述切換電路19可切換之多個低頻模態之其中四個。15 is a graph showing the total radiation efficiency of the antenna structure 100 when operating in a low frequency mode, a GPS mode, and an intermediate frequency mode. Wherein, the curve S151 is the total radiation efficiency when the antenna structure 100 operates at LTE-A 734-756 MHz. Curve S152 is the total radiation efficiency of the antenna structure 100 operating at LTE-A 791-821 MHz. Curve S153 is the total radiation efficiency of the antenna structure 100 operating at LTE-A 869-894 MHz. Curve S154 is the total radiation efficiency of the antenna structure 100 operating at LTE-A 925-960 MHz. Curve S155 is the total radiation efficiency of the antenna structure 100 operating at 1575 MHz. Curve S156 is the total radiation efficiency of the antenna structure 100 operating at LTE-A 1805-2170 MHz. Obviously, the curves S151-S154 respectively correspond to four different frequency bands, and respectively correspond to four of the plurality of low frequency modes that the switching circuit 19 can switch.

圖16為所述天線結構100工作於高頻模態(即LTE-A 2300-2400MHz及LTE-A 2496-2690MHz)及WIFI 2.4G模態時之S參數(散射參數)曲線圖。圖17為所述天線結構100工作於高頻模態(即LTE-A 2300-2400MHz及LTE-A 2496-2690MHz)及WIFI 2.4G模態時之輻射效率圖。16 is a graph of S parameters (scattering parameters) when the antenna structure 100 operates in a high frequency mode (ie, LTE-A 2300-2400 MHz and LTE-A 2496-2690 MHz) and a WIFI 2.4G mode. 17 is a graph showing the radiation efficiency of the antenna structure 100 when operating in a high frequency mode (ie, LTE-A 2300-2400 MHz and LTE-A 2496-2690 MHz) and a WIFI 2.4G mode.

顯然,從圖14至圖17可知,所述天線結構100可工作於相應之低頻頻段,例如LTE-A 734-960MHz頻段。另外,所述天線結構100還可工作於GPS頻段、中頻段(LTE-A 1805-2170MHz頻段)、高頻段(即LTE-A 2300-2400MHz、LTE-A 2496-2690MHz)及WIFI 2.4G頻段,即涵蓋至低、中、高頻、GPS頻段、WIFI 2.4G頻段,頻率範圍較廣,且當所述天線結構100工作於上述頻段時,其工作頻率均可滿足天線工作設計要求,並具有較佳之輻射效率。Obviously, as can be seen from FIG. 14 to FIG. 17, the antenna structure 100 can operate in a corresponding low frequency band, such as the LTE-A 734-960 MHz band. In addition, the antenna structure 100 can also work in the GPS frequency band, the middle frequency band (LTE-A 1805-2170 MHz frequency band), the high frequency band (ie, LTE-A 2300-2400 MHz, LTE-A 2496-2690 MHz), and the WIFI 2.4G frequency band. That is to cover the low, medium, high frequency, GPS frequency band, WIFI 2.4G frequency band, the frequency range is wide, and when the antenna structure 100 works in the above frequency band, the working frequency can meet the antenna working design requirements, and has Good radiation efficiency.

如前面各實施例所述,所述天線結構100藉由設置所述開槽118、斷點119以及縫隙120,以自所述前框111劃分出第一輻射部A1及第二輻射部A2之第一分支B1、第二分支B2。所述天線結構100還設置有第一饋入源13及第二饋入源15,進而使得所述第一饋入源13及第二饋入源15之電流可分別饋入所述第二輻射部A2之第一分支B1、第二分支B2及所述第一輻射部A1。如此,所述第二輻射部A2之第一分支B1可激發第一模態以產生低頻頻段之輻射訊號。所述第二輻射部A2之第二分支B2可激發第二模態以產生中頻頻段之輻射訊號。所述第一輻射部A1可激發第三模態以產生高頻頻段之輻射訊號。因此無線通訊裝置400可使用長期演進技術升級版(LTE-Advanced)之載波聚合(CA,Carrier Aggregation)技術同時於多個不同頻段接收或發送無線訊號以增加傳輸頻寬。As described in the foregoing embodiments, the antenna structure 100 is configured to divide the first radiating portion A1 and the second radiating portion A2 from the front frame 111 by providing the slot 118, the break point 119, and the slot 120. The first branch B1 and the second branch B2. The antenna structure 100 is further provided with a first feed source 13 and a second feed source 15, so that currents of the first feed source 13 and the second feed source 15 can be respectively fed into the second radiation. The first branch B1 of the portion A2, the second branch B2, and the first radiating portion A1. As such, the first branch B1 of the second radiating portion A2 can excite the first mode to generate a radiated signal in the low frequency band. The second branch B2 of the second radiating portion A2 can excite the second mode to generate a radiation signal of the intermediate frequency band. The first radiating portion A1 can excite the third mode to generate a radiation signal of a high frequency band. Therefore, the wireless communication device 400 can simultaneously receive or transmit wireless signals in a plurality of different frequency bands to increase the transmission bandwidth by using Carrier Aggregation (CA) technology of LTE-Advanced.

另外,該天線結構100藉由設置所述殼體11,且所述殼體11上之開槽118、斷點119及縫隙120均設置於所述前框111及邊框113上,並未設置於所述背板112上,使得所述背板112構成全金屬結構,即所述背板112上並沒有絕緣之開槽、斷線或斷點,使得所述背板112可避免由於開槽、斷線或斷點之設置而影響背板112之完整性與美觀性。In addition, the antenna structure 100 is provided with the housing 11, and the slot 118, the break point 119 and the slot 120 on the housing 11 are disposed on the front frame 111 and the frame 113, and are not disposed on the antenna frame 100. The backing plate 112 is configured to have an all-metal structure, that is, the backing plate 112 has no insulating slots, broken lines or break points, so that the backing plate 112 can avoid slotting, The setting of the broken line or breakpoint affects the integrity and aesthetics of the backing plate 112.

實施例2Example 2

請參閱圖18,本發明第二較佳實施方式提供一種天線結構200,其可應用於行動電話、個人數位助理等無線通訊裝置300中,用以發射、接收無線電波以傳遞、交換無線訊號。Referring to FIG. 18, a second preferred embodiment of the present invention provides an antenna structure 200, which can be applied to a wireless communication device 300 such as a mobile phone or a personal digital assistant for transmitting and receiving radio waves to transmit and exchange wireless signals.

請一併參閱圖19及圖20,所述天線結構200包括殼體21、第一饋入源22、匹配電路23及第一接地部24。所述殼體21可為所述無線通訊裝置300之外殼。於本實施例中,所述殼體21由金屬材料製成。所述殼體21包括前框211、背板212及邊框213。所述前框211、背板212及邊框213可是一體成型。所述前框211、背板212以及邊框213構成所述無線通訊裝置300之外殼。所述前框211上設置有一開口(圖未標),用於容置所述無線通訊裝置300之顯示單元301。可理解,所述顯示單元301具有一顯示平面,該顯示平面裸露於該開口,且該顯示平面與所述背板212大致平行設置。Referring to FIG. 19 and FIG. 20 , the antenna structure 200 includes a housing 21 , a first feed source 22 , a matching circuit 23 , and a first ground portion 24 . The housing 21 can be an outer casing of the wireless communication device 300. In the present embodiment, the housing 21 is made of a metal material. The housing 21 includes a front frame 211, a back plate 212, and a frame 213. The front frame 211, the back plate 212 and the frame 213 may be integrally formed. The front frame 211, the back plate 212 and the frame 213 constitute an outer casing of the wireless communication device 300. An opening (not shown) is disposed on the front frame 211 for receiving the display unit 301 of the wireless communication device 300. It can be understood that the display unit 301 has a display plane, the display plane is exposed to the opening, and the display plane is disposed substantially parallel to the backboard 212.

請一併參閱圖21,所述背板212與所述前框211相對設置。所述背板212與邊框213直接連接,所述背板212與邊框213之間沒有空隙。所述背板212為一體成型之單一金屬片,為顯露相機鏡頭304與閃光燈305等元件,所述背板112設置開孔306、307。所述背板112其上並沒有設置任何用於分割所述背板212之絕緣之開槽、斷線或斷點。所述背板212相當於所述天線結構200與所述無線通訊裝置300之地。Referring to FIG. 21 together, the backboard 212 is disposed opposite to the front frame 211. The back plate 212 is directly connected to the frame 213, and there is no gap between the back plate 212 and the frame 213. The back plate 212 is an integrally formed single metal piece for exposing components such as the camera lens 304 and the flash 305, and the back plate 112 is provided with openings 306, 307. The backing plate 112 is not provided with any slot, break or break point for separating the insulation of the backing plate 212. The backplane 212 corresponds to the antenna structure 200 and the ground of the wireless communication device 300.

所述邊框213夾設於所述前框211與所述背板212之間,且分別環繞所述前框211及所述背板212之周緣設置,以與所述顯示單元301、所述前框211以及背板212共同圍成一容置空間214。所述容置空間214用以容置所述無線通訊裝置300之電路板、處理單元等電子元件或電路模組於其內。The frame 213 is disposed between the front frame 211 and the back plate 212, and is disposed around the periphery of the front frame 211 and the back plate 212, respectively, to be opposite to the display unit 301 and the front The frame 211 and the back plate 212 together define an accommodating space 214. The accommodating space 214 is configured to receive electronic components or circuit modules of the circuit board, the processing unit, and the like of the wireless communication device 300.

所述邊框213至少包括末端部215、第一側部216以及第二側部217。於本實施例中,所述末端部215為所述無線通訊裝置300之底端。所述末端部215連接所述前框211與所述背板212。所述第一側部216與所述第二側部217相對設置,兩者分別設置於所述末端部215之兩端,優選垂直設置。所述第一側部216與所述第二側部217亦連接所述前框211與所述背板212。The frame 213 includes at least a tip end portion 215, a first side portion 216, and a second side portion 217. In the embodiment, the end portion 215 is the bottom end of the wireless communication device 300. The end portion 215 connects the front frame 211 and the back plate 212. The first side portion 216 is disposed opposite to the second side portion 217, and is disposed at two ends of the end portion 215, preferably vertically. The first side portion 216 and the second side portion 217 are also connected to the front frame 211 and the back plate 212.

所述邊框213上還開設有第一開孔218、第二開孔219及開槽220。所述前框211上開設有第一斷點221及第二斷點222。所述第一開孔218及第二開孔219均開設於所述末端部215上,兩者間隔設置且均貫通所述末端部215。A first opening 218, a second opening 219 and a slot 220 are defined in the frame 213. A first break point 221 and a second break point 222 are defined in the front frame 211 . The first opening 218 and the second opening 219 are both formed on the end portion 215 , and both are spaced apart and penetrate the end portion 215 .

所述無線通訊裝置300還包括至少一電子元件。於本實施例中,所述無線通訊裝置300包括第一電子元件302及第二電子元件303。所述第一電子元件302為一耳機介面模組,其設置於所述容置空間214內,且鄰近所述第一側部216設置。所述第一電子元件302與所述第一開孔218相對應,以使得所述第一電子元件302從所述第一開孔218部分露出。如此用戶可將一耳機藉由所述第一開孔218插入,進而與所述第一電子元件302建立電性連接。The wireless communication device 300 also includes at least one electronic component. In the embodiment, the wireless communication device 300 includes a first electronic component 302 and a second electronic component 303. The first electronic component 302 is a headphone interface module disposed in the accommodating space 214 and disposed adjacent to the first side portion 216 . The first electronic component 302 corresponds to the first opening 218 such that the first electronic component 302 is partially exposed from the first opening 218. Thus, the user can insert an earphone through the first opening 218 to establish an electrical connection with the first electronic component 302.

所述第二電子元件303為一USB模組,其設置於所述容置空間214內,且位於所述第一電子元件302與所述第二側部217之間。所述第二電子元件303與所述第二開孔219相對應,以使得所述第二電子元件303從所述第二開孔219部分露出。如此使用者可將一USB設備藉由所述第二開孔219插入,進而與所述第二電子元件303建立電性連接。The second electronic component 303 is a USB module disposed in the accommodating space 214 and located between the first electronic component 302 and the second side 217 . The second electronic component 303 corresponds to the second opening 219 such that the second electronic component 303 is partially exposed from the second opening 219. Therefore, the user can insert a USB device through the second opening 219 to establish an electrical connection with the second electronic component 303.

於本實施例中,所述開槽220佈設於所述末端部215上,且連通所述第一開孔218及第二開孔219,並且分別延伸至所述第一側部216及第二側部217。In the embodiment, the slot 220 is disposed on the end portion 215 and communicates with the first opening 218 and the second opening 219, and extends to the first side portion 216 and the second portion, respectively. Side 217.

所述第一斷點221及第二斷點222均與所述開槽220連通,並延伸至隔斷所述前框211。於本實施例中,所述第一斷點221開設於所述前框211上,且與所述開槽220佈設於所述第一側部216之第一末端D1連通。所述第二斷點222開設於所述前框211上,且與所述開槽220佈設於所述第二側部217之第二末端D2連通。如此,所述開槽220、第一斷點221及第二斷點222共同將所述殼體21劃分為相互間隔設置之第一部分F1及第二部分F2。其中,所述殼體21中由所述開槽220、第一斷點221及第二斷點222共同圍成之部分構成所述第一部分F1,所述殼體21剩餘之部分則構成所述第二部分F2。於本實施例中,所述第一部分F1構成所述天線結構200之天線結構,用以接收與/或發射無線電波以傳遞、交換無線訊號。所述第二部分F2接地。The first break point 221 and the second break point 222 are both in communication with the slot 220 and extend to block the front frame 211. In the embodiment, the first break point 221 is formed on the front frame 211 and communicates with the first end D1 of the first side portion 216 . The second break point 222 is disposed on the front frame 211 and communicates with the slot 220 disposed at the second end D2 of the second side portion 217 . As such, the slot 220, the first break point 221, and the second break point 222 collectively divide the housing 21 into a first portion F1 and a second portion F2 that are spaced apart from each other. The portion of the housing 21 that is enclosed by the slot 220, the first break point 221, and the second break point 222 constitutes the first portion F1, and the remaining portion of the housing 21 constitutes the The second part is F2. In this embodiment, the first portion F1 constitutes an antenna structure of the antenna structure 200 for receiving and/or transmitting radio waves to transmit and exchange wireless signals. The second portion F2 is grounded.

可理解,於本實施例中,所述開槽220開設於所述邊框213靠近所述背板212之一端,並延伸至所述前框211之邊緣,以使得所述第一部分F1完全由部分所述前框212構成。當然,於其他實施例中,所述開槽220之開設位置亦可根據具體需求進行調整。例如,所述開槽220開設於所述邊框213靠近所述背板212之一端,並朝所述前框211所在方向延伸,以使得所述第一部分F1由部分所述前框211及部分所述邊框213構成。It can be understood that, in this embodiment, the slot 220 is disposed at one end of the frame 213 near the back plate 212 and extends to an edge of the front frame 211 such that the first portion F1 is completely partially The front frame 212 is constructed. Of course, in other embodiments, the opening position of the slot 220 can also be adjusted according to specific needs. For example, the slot 220 is disposed at one end of the frame 213 near the back plate 212 and extends toward the front frame 211 such that the first portion F1 is partially covered by the front frame 211 and the portion The frame 213 is constructed.

可理解,於其他實施例中,所述開槽220亦可僅設置於所述末端部215,而未延伸至所述第一側部216及第二側部217中之任何一個,或者所述開槽220設置於所述末端部215,且僅沿延伸至所述第一側部216及第二側部217中之其中之一。如此,所述第一斷點221及第二斷點222之位置亦可根據所述開槽220之位置進行調整。例如,所述第一斷點221及第二斷點222可均開設於所述前框211對應所述末端部215之位置。例如,所述第一斷點221及第二斷點222中之一個可開設於所述前框211對應所述末端部215之位置,而所述第一斷點221及第二斷點222中之另一個可開設於所述前框211對應所述第一側部216或第二側部217之位置。顯然,所述開槽220之形狀、位置以及所述第一斷點221及第二斷點222於所述邊框212上之位置均可根據具體需求進行調整,僅需保證所述開槽220、所述第一斷點221及第二斷點222可共同將所述殼體21劃分為間隔設置之第一部分F1及第二部分F2即可。It can be understood that in other embodiments, the slot 220 may be disposed only on the end portion 215 without extending to any one of the first side portion 216 and the second side portion 217, or The slot 220 is disposed at the end portion 215 and extends only to one of the first side portion 216 and the second side portion 217. Thus, the positions of the first break point 221 and the second break point 222 can also be adjusted according to the position of the slot 220. For example, the first break point 221 and the second break point 222 may both be located at positions where the front frame 211 corresponds to the end portion 215. For example, one of the first break point 221 and the second break point 222 may be located at a position corresponding to the end portion 215 of the front frame 211, and the first break point 221 and the second break point 222 are The other one can be opened at a position where the front frame 211 corresponds to the first side portion 216 or the second side portion 217. Obviously, the shape and position of the slot 220 and the position of the first break point 221 and the second break point 222 on the frame 212 can be adjusted according to specific requirements, and only the slot 220 needs to be ensured. The first break point 221 and the second break point 222 may collectively divide the housing 21 into the first portion F1 and the second portion F2 that are spaced apart.

可理解,於本實施例中,除了第一開孔218與第二開孔219之位置以外,所述開槽220、所述第一斷點221及第二斷點222內均填充有絕緣材料(例如塑膠、橡膠、玻璃、木材、陶瓷等,但不以此為限),進而區隔所述第一部分F1與第二部分F2。It can be understood that, in this embodiment, in addition to the positions of the first opening 218 and the second opening 219, the slot 220, the first breaking point 221 and the second breaking point 222 are filled with an insulating material. (for example, plastic, rubber, glass, wood, ceramics, etc., but not limited thereto), thereby separating the first portion F1 and the second portion F2.

可理解,於本實施例中,所述第一饋入源22設置於所述容置空間214內,且位於所述第二電子元件303與所述第二側部217之間,並鄰近所述第二電子元件303設置。所述第一饋入源22藉由所述匹配電路23電連接至所述第一部分F1,以為所述第一部分F1饋入電流,並將所述第一部分F1劃分為兩部分,即第一分支H1及第二分支H2。其中,所述第一饋入源22一側之前框211直至其延伸至所述前框211設置有所述第一斷點221之部分形成所述第一分支H1。所述第一饋入源22另一側之前框211直至其延伸至所述前框211設置有所述第二斷點222之部分形成所述第二分支H2。於本實施例中,所述第一饋入源22開設之位置並非對應到所述第一部分F1之中間,因此所述第一分支H1之長度大於第二分支H2之長度。It can be understood that, in this embodiment, the first feed source 22 is disposed in the accommodating space 214 and located between the second electronic component 303 and the second side 217, and adjacent to the The second electronic component 303 is disposed. The first feed source 22 is electrically connected to the first portion F1 by the matching circuit 23 to feed current to the first portion F1, and divide the first portion F1 into two parts, that is, the first branch H1 and the second branch H2. The first feeding source 22 side front frame 211 extends until the portion of the front frame 211 where the first breaking point 221 is disposed to form the first branch H1. The portion of the first feed source 22 on the other side of the front frame 211 until it extends to the front frame 211 where the second break point 222 is disposed forms the second branch H2. In this embodiment, the position where the first feed source 22 is opened does not correspond to the middle of the first portion F1, so the length of the first branch H1 is greater than the length of the second branch H2.

所述第一接地部24大致呈矩形條狀,其設置於所述容置空間214內,且位於所述第一饋入源22與所述第二側部217之間。所述第一接地部24之一端電連接至所述第二分支H2,另一端電連接至所述背板212,即接地,進而為所述第二分支H2提供接地。The first ground portion 24 is substantially in the shape of a strip, and is disposed in the accommodating space 214 and located between the first feed source 22 and the second side portion 217 . One end of the first grounding portion 24 is electrically connected to the second branch H2, and the other end is electrically connected to the backing plate 212, that is, grounded, thereby providing grounding for the second branch H2.

可理解,於本實施例中,當電流自所述第一饋入源22進入後,電流將流入所述第一部分F1之第一分支H1,並流向所述第一斷點221,進而使得所述第一分支H1激發一第一模態以產生第一頻段之輻射訊號。本實施例中,所述第一模態為一低頻模態。所述第一頻段為LTE-A 704-960MHz頻段。另外,當電流自所述第一饋入源22進入後,電流還將流入所述第二分支H2,並流向所述第二斷點222,且藉由所述第一接地部24接地,進而使得所述第二分支H2激發一第二模態以產生第二頻段之輻射訊號。本實施例中,所述第二模態為一中頻模態。所述第二頻段之頻率高於所述第一頻段之頻率。所述第二頻段為1710-1990MHz頻段。It can be understood that, in this embodiment, when a current enters from the first feed source 22, current will flow into the first branch H1 of the first portion F1 and flow to the first break point 221, thereby making The first branch H1 excites a first mode to generate a radiation signal of the first frequency band. In this embodiment, the first mode is a low frequency mode. The first frequency band is an LTE-A 704-960 MHz frequency band. In addition, when a current enters from the first feed source 22, current will also flow into the second branch H2 and flow to the second break point 222, and the ground is grounded by the first ground portion 24, thereby further The second branch H2 is caused to excite a second mode to generate a radiation signal of the second frequency band. In this embodiment, the second mode is an intermediate frequency mode. The frequency of the second frequency band is higher than the frequency of the first frequency band. The second frequency band is the 1710-1990 MHz frequency band.

可理解,於其他實施例中,為調節所述第一頻段之頻寬,即使得所述天線結構200具有較佳之低頻頻寬,所述天線結構200還包括第一切換電路25。所述第一切換電路25設置於所述容置空間214內,且位於所述第一電子元件302及第二電子元件303之間。所述第一切換電路25之一端電連接至所述第一分支H1,另一端電連接至所述背板212,即接地。It can be understood that, in other embodiments, to adjust the bandwidth of the first frequency band, that is, the antenna structure 200 has a preferred low frequency bandwidth, the antenna structure 200 further includes a first switching circuit 25. The first switching circuit 25 is disposed in the accommodating space 214 and located between the first electronic component 302 and the second electronic component 303. One end of the first switching circuit 25 is electrically connected to the first branch H1, and the other end is electrically connected to the backboard 212, that is, grounded.

請一併參閱圖22,所述第一切換電路25包括切換單元251及至少一切換元件253。所述切換單元251電連接至所述第一分支H1。所述切換元件253可為電感、電容、或者電感與電容之組合。所述切換元件253之間相互並聯,且其一端電連接至所述切換單元251,另一端電連接至所述背板212,即接地。如此,藉由控制所述切換單元251之切換,可使得所述第一分支H1切換至不同之切換元件253。由於每一個切換元件253具有不同之阻抗,因此藉由所述切換單元251之切換,可調整所述第一分支H1之第一模態所產生之第一頻段。Referring to FIG. 22 together, the first switching circuit 25 includes a switching unit 251 and at least one switching element 253. The switching unit 251 is electrically connected to the first branch H1. The switching element 253 can be an inductor, a capacitor, or a combination of an inductor and a capacitor. The switching elements 253 are connected in parallel with each other, and one end thereof is electrically connected to the switching unit 251, and the other end is electrically connected to the backing plate 212, that is, grounded. Thus, by controlling the switching of the switching unit 251, the first branch H1 can be switched to a different switching element 253. Since each switching element 253 has a different impedance, the first frequency band generated by the first mode of the first branch H1 can be adjusted by switching of the switching unit 251.

可理解,於本實施例中,所述第一分支H1還可額外激發一第三模態以產生第三頻段之輻射訊號。具體請一併參閱圖23及圖24,所述第一切換電路25還包括諧振電路255。請參閱圖23,於其中一實施例中,所述諧振電路255之數量為一個,所述諧振電路255包括相互串聯之電感L及電容C。所述諧振電路255電連接於所述第一分支H1及背板212之間,且與所述切換單元251及至少一個切換元件253並聯設置。It can be understood that, in this embodiment, the first branch H1 may additionally excite a third mode to generate a radiation signal of the third frequency band. For details, please refer to FIG. 23 and FIG. 24 , the first switching circuit 25 further includes a resonant circuit 255 . Referring to FIG. 23, in one embodiment, the number of the resonant circuits 255 is one, and the resonant circuit 255 includes an inductor L and a capacitor C connected in series. The resonant circuit 255 is electrically connected between the first branch H1 and the backplane 212, and is disposed in parallel with the switching unit 251 and the at least one switching component 253.

請參閱圖24,於另外一實施例中,所述諧振電路255之數量與所述切換元件253之數量一致,即為多個。每一諧振電路255包括相互串聯之電感L1-Ln及電容C1-Cn。每一個所述諧振電路255分別電連接於切換單元251及背板212之間,並與對應之切換元件253並聯設置。Referring to FIG. 24, in another embodiment, the number of the resonant circuits 255 is the same as the number of the switching elements 253, that is, multiple. Each of the resonant circuits 255 includes inductors L1-Ln and capacitors C1-Cn connected in series with each other. Each of the resonant circuits 255 is electrically connected between the switching unit 251 and the backing plate 212, and is disposed in parallel with the corresponding switching element 253.

圖25為於圖23所示所述第一切換電路25之切換單元251一側並聯一個諧振電路255,且所述諧振電路255包括相互串聯之電感L及電容C時,所述第一分支H1之S參數(散射參數)與頻率之間之關係原理圖。其中,假設當所述第一切換電路25未增加圖23所示所述諧振電路255時,所述天線結構200之第一分支H1工作於第一模態(請參曲線S251)。當所述第一切換電路25增加所述諧振電路255時,所述諧振電路255可使得所述第一分支H1額外共振出一窄頻模態,即第三模態(請參曲線S252),以產生第三頻段之輻射訊號,即可有效增加所述天線結構200之應用頻段,達到多頻或寬頻應用。於一實施例中,所述第三頻段可是中頻段,所述第三模態亦就是中頻諧振模態。所述第三頻段之頻率高於第二頻段之頻率。所述第三頻段為2110-2170MHz頻段。25 is a parallel circuit 255 on the side of the switching unit 251 of the first switching circuit 25 shown in FIG. 23, and the resonant circuit 255 includes an inductor L and a capacitor C connected in series, the first branch H1 Schematic diagram of the relationship between S-parameters (scattering parameters) and frequency. It is assumed that when the first switching circuit 25 does not increase the resonant circuit 255 shown in FIG. 23, the first branch H1 of the antenna structure 200 operates in the first mode (refer to curve S251). When the first switching circuit 25 increases the resonant circuit 255, the resonant circuit 255 may cause the first branch H1 to additionally resonate to a narrow frequency mode, that is, a third mode (refer to curve S252), In order to generate the radiation signal of the third frequency band, the application frequency band of the antenna structure 200 can be effectively increased to achieve multi-frequency or broadband application. In an embodiment, the third frequency band may be a medium frequency band, and the third mode is also an intermediate frequency resonant mode. The frequency of the third frequency band is higher than the frequency of the second frequency band. The third frequency band is a frequency band of 2110-2170 MHz.

圖26為於圖24所示所述第一切換電路25中每一切換元件253一側並聯一個諧振電路255,且所述諧振電路255包括相互串聯之電感L1-Ln及電容C1-Cn時,所述第一分支H1之S參數(散射參數)與頻率之間之關係原理圖。其中,假設當所述第一切換電路25未增加圖24所示所述諧振電路255時,所述天線結構200之第一分支H1工作於第一模態(請參曲線S261)。如此當所述第一切換電路25增加所述諧振電路255時,所述諧振電路255可使得所述第一分支H1額外共振出所述窄頻模態(請參曲線S262),亦就是中頻共振模態,即可有效增加所述天線結構200之應用頻段,達到多頻或寬頻應用。另外,藉由設置所述諧振電路255中電感L1-Ln之電感值與所述電容C1-Cn之電容值,可決定所述第一模態切換時所述窄頻模態之頻段。例如,於其中一個實施例中,例如圖26所示,可藉由設置所述諧振電路255中之電感值與電容值,使切換單元251切換至不同之切換元件253時,所述天線結構200之窄頻模態(即第三模態)亦隨之切換,例如可由f1移動至fn,移動範圍十分廣泛。26 is a parallel circuit 255 on the side of each switching element 253 in the first switching circuit 25 shown in FIG. 24, and the resonant circuit 255 includes inductors L1-Ln and capacitors C1-Cn connected in series with each other. A schematic diagram of the relationship between the S parameter (scattering parameter) of the first branch H1 and the frequency. It is assumed that when the first switching circuit 25 does not increase the resonant circuit 255 shown in FIG. 24, the first branch H1 of the antenna structure 200 operates in the first mode (refer to curve S261). Thus, when the first switching circuit 25 increases the resonant circuit 255, the resonant circuit 255 can cause the first branch H1 to additionally resonate out of the narrowband mode (refer to curve S262), that is, the intermediate frequency. The resonant mode can effectively increase the application frequency band of the antenna structure 200 to achieve multi-frequency or wide-band applications. In addition, by setting the inductance value of the inductance L1-Ln in the resonant circuit 255 and the capacitance value of the capacitance C1-Cn, the frequency band of the narrow-band mode at the first mode switching can be determined. For example, in one embodiment, as shown in FIG. 26, the antenna structure 200 can be switched when the switching unit 251 is switched to a different switching element 253 by setting the inductance value and the capacitance value in the resonant circuit 255. The narrow-band mode (ie, the third mode) is also switched, for example, from f1 to fn, and the range of motion is very wide.

可理解,於另一實施例中,還可藉由設置所述諧振電路255中之電感值與電容值而固定所述窄頻模態之頻段,從而使所述切換單元251無論切換至哪一個切換元件253,所述窄頻模態之頻段均固定不動。It can be understood that, in another embodiment, the frequency band of the narrowband mode can be fixed by setting the inductance value and the capacitance value in the resonant circuit 255, so that the switching unit 251 switches to which one. The switching element 253 has a fixed frequency band of the narrow frequency mode.

可理解,於其他實施例中,所述諧振電路255不局限於包括所述電感L及電容C,其還可由其他之諧振元件組成。例如,請一併參閱圖27及圖28,於另外一實施例中,所述諧振電路255僅包括電容C或電容C1-Cn。如此,請參閱圖29,為電壓駐波比(standing wave ratio,SWR)與頻率之關係示意圖。當改變所述電容C或電容C1-Cn之電容值時,可有效移動所述窄頻模態f1之倍頻模態fh,移動範圍十分廣泛。It can be understood that in other embodiments, the resonant circuit 255 is not limited to include the inductor L and the capacitor C, and may also be composed of other resonant components. For example, please refer to FIG. 27 and FIG. 28 together. In another embodiment, the resonant circuit 255 includes only the capacitor C or the capacitors C1-Cn. Thus, please refer to FIG. 29 , which is a schematic diagram of the relationship between the standing wave ratio (SWR) and the frequency. When the capacitance value of the capacitor C or the capacitance C1-Cn is changed, the frequency doubling mode fh of the narrow frequency mode f1 can be effectively moved, and the range of motion is very wide.

可理解,請再次參閱圖18,於其他實施例,所述天線結構200還包括輻射體26、第二饋入源27、第二接地部28及第二切換電路29。It can be understood that, referring to FIG. 18 again, in other embodiments, the antenna structure 200 further includes a radiator 26, a second feed source 27, a second ground portion 28, and a second switching circuit 29.

於本實施例中,所述輻射體26設置於所述容置空間214內,且鄰近所述第一斷點221設置,並與所述背板212間隔設置。於本實施例中,所述輻射體26大致呈直條狀,跨越所述第一電子元件302之上方且與所述第一電子元件302間隔設置。所述輻射體26之一端鄰近所述第一電子元件302設置,另一端沿平行所述末端部215且靠近所述第二側部217之方向延伸,並跨過所述第一電子元件302,以繼續沿平行所述末端部215且靠近所述第二側部217之方向延伸。In the present embodiment, the radiator 26 is disposed in the accommodating space 214 and disposed adjacent to the first break point 221 and spaced apart from the back plate 212. In the present embodiment, the radiator 26 is substantially straight and spans above the first electronic component 302 and spaced apart from the first electronic component 302. One end of the radiator 26 is disposed adjacent to the first electronic component 302, and the other end extends in a direction parallel to the end portion 215 and adjacent to the second side portion 217, and spans the first electronic component 302, The continuation extends in a direction parallel to the distal end portion 215 and adjacent to the second side portion 217.

所述第二饋入源27設置於所述第一側部216與所述第一電子元件302之間。所述第二饋入源27之一端電連接至所述輻射體26靠近所述第二接地部28之一端,另一端電連接至所述背板212,即接地,用以為所述輻射體26饋入電流訊號。所述第二接地部28之一端電連接至所述輻射體26,另一端電連接至所述背板212,即接地,進而為所述輻射體26提供接地。如此,當電流自所述第二饋入源27進入後,將流過所述輻射體26,進而使得所述輻射體26激發一第四模態以產生第四頻段之輻射訊號。於本實施例中,所述第四模態為高頻模態,所述第四頻段之頻率高於所述第三頻段之頻率。The second feed source 27 is disposed between the first side portion 216 and the first electronic component 302. One end of the second feed source 27 is electrically connected to one end of the radiator 26 near the second ground portion 28, and the other end is electrically connected to the back plate 212, that is, grounded, for the radiator 26 Feed current signal. One end of the second grounding portion 28 is electrically connected to the radiator 26, and the other end is electrically connected to the backing plate 212, that is, grounded, thereby providing grounding for the radiator 26. Thus, when current enters from the second feed source 27, it will flow through the radiator 26, thereby causing the radiator 26 to excite a fourth mode to generate a radiation signal of the fourth frequency band. In this embodiment, the fourth mode is a high frequency mode, and the frequency of the fourth frequency band is higher than the frequency of the third frequency band.

所述第二饋入源27與第二接地部28設置於所述第一電子元件302靠近所述第一側部216之一側,所述第二切換電路29設置於所述第一電子元件302靠近所述第二側部217之一側。所述第二切換電路29之一端電連接至所述輻射體26之中部位置,另一端電連接至所述背板212,即接地。所述第二切換電路29用於調整所述輻射體26之高頻模態之頻段,使其高頻模態涵蓋LTE-A 2300-2400MHz及LTE-A 2496-2690MHz之應用頻段,即LTE-A 2300-2690MHz頻段。該第二切換電路29之具體電路結構及工作原理可參閱圖22之第一切換電路25之描述,於此不再贅述。The second feeding source 27 and the second grounding portion 28 are disposed on one side of the first electronic component 302 near the first side portion 216, and the second switching circuit 29 is disposed on the first electronic component 302 is adjacent to one side of the second side portion 217. One end of the second switching circuit 29 is electrically connected to a position inside the radiator 26, and the other end is electrically connected to the back plate 212, that is, grounded. The second switching circuit 29 is configured to adjust a frequency band of the high frequency mode of the radiator 26 such that the high frequency mode covers an application frequency band of LTE-A 2300-2400 MHz and LTE-A 2496-2690 MHz, that is, LTE-A 2300-2690 MHz Frequency band. The specific circuit structure and working principle of the second switching circuit 29 can be referred to the description of the first switching circuit 25 of FIG. 22, and details are not described herein again.

圖30為所述天線結構200之電流走向示意圖。顯然,當電流自所述第一饋入源22進入後,電流將流經所述第一分支H1,並流向所述第一斷點221(參路徑I1),進而激發出所述第一模態以產生第一頻段之輻射訊號。同時,當電流自所述第一饋入源22饋入後,所述電流還將流經所述第二分支H2,並流向所述第二斷點222(參路徑I2),最後藉由所述第一接地部24接地,進而激發出所述第二模態以產生第二頻段之輻射訊號。另外,由於所述天線結構200設置有所述第一切換電路25,因此可利用所述第一切換電路25之切換,進而切換所述第一模態,同時不影響中、高頻之操作。FIG. 30 is a schematic diagram of current flow of the antenna structure 200. Obviously, when current enters from the first feed source 22, current will flow through the first branch H1 and flow to the first break point 221 (refer to the path I1), thereby exciting the first mode. State to generate a radiation signal of the first frequency band. Meanwhile, when a current is fed from the first feed source 22, the current will also flow through the second branch H2 and flow to the second breakpoint 222 (refer to the path I2), and finally by The first grounding portion 24 is grounded to excite the second mode to generate a radiation signal of the second frequency band. In addition, since the antenna structure 200 is provided with the first switching circuit 25, the switching of the first switching circuit 25 can be utilized, thereby switching the first mode while not affecting the operation of the medium and high frequencies.

再者,由於所述天線結構200設置有所述諧振電路255。如此,可使得流過所述第一分支H1中之電流流向所述第一切換電路25中之諧振電路255,並最終流向所述第一斷點221(參路徑I3),以使得所述第一分支H1搭配所述諧振電路255,進而使得所述第一分支H1額外激發出所述第三模態以產生第三頻段之輻射訊號。另外,當電流自所述第二饋入源27饋入後,將流經所述輻射體26(參路徑I4),進而激發出所述第四模態以產生第四頻段之輻射訊號。顯然,結合圖22與圖30可知,所述背板212相當於所述天線結構200之地。Furthermore, since the antenna structure 200 is provided with the resonant circuit 255. In this way, the current flowing in the first branch H1 can be caused to flow to the resonant circuit 255 in the first switching circuit 25, and finally to the first break point 221 (refer to the path I3), so that the first A branch H1 is coupled to the resonant circuit 255, such that the first branch H1 additionally excites the third mode to generate a radiation signal of the third frequency band. In addition, when a current is fed from the second feed source 27, it will flow through the radiator 26 (refer to the path I4), thereby exciting the fourth mode to generate a radiation signal of the fourth frequency band. Obviously, as can be seen from FIG. 22 and FIG. 30, the back plate 212 corresponds to the ground of the antenna structure 200.

可理解,所述背板212可作為所述天線結構200與所述無線通訊裝置300之地。於另一實施例中,於所述顯示單元301朝向所述背板212那一面可設置用於屏蔽電磁干擾之屏蔽罩(shielding mask)或支撐所述顯示單元301之中框。所述屏蔽罩或中框以金屬材料製作。所述屏蔽罩或中框可與所述背板212相連接以作為所述天線結構200與所述無線通訊裝置300之地。於上述之每一處接地,所述屏蔽罩或中框可取代所述背板212以供所述天線結構100或所述無線通訊裝置300接地。It can be understood that the backplane 212 can serve as the ground structure 200 and the wireless communication device 300. In another embodiment, a shielding mask for shielding electromagnetic interference or supporting a frame in the display unit 301 may be disposed on a side of the display unit 301 facing the backboard 212. The shield or the middle frame is made of a metal material. The shield or middle frame may be coupled to the back plate 212 to serve as the ground structure 200 and the wireless communication device 300. Grounded at each of the above, the shield or middle frame can replace the backplane 212 for grounding the antenna structure 100 or the wireless communication device 300.

圖31為所述天線結構200工作於LTE-A低頻模態、中頻模態以及高頻模態時之S參數(散射參數)曲線圖。其中,曲線S311為所述天線結構200工作於704-746MHz時之S11值。曲線S312為所述天線結構200工作於746-787MHz時之S11值。曲線S313為所述天線結構200工作於791-862MHz時之S11值。曲線S314為所述天線結構200工作於824-894MHz時之S11值。曲線S315為所述天線結構200工作於880-960MHz時之S11值。曲線S316為所述天線結構200工作於1710-2170MHz時之S11值。曲線S317為所述天線結構200工作於2300-2400MHz時之S11值。曲線S318為所述天線結構200工作於2500-2690MHz時之S11值。顯然,曲線S311-S315分別對應五個不同頻段,並分別對應所述第一切換電路25可切換之多個低頻模態之其中五個。FIG. 31 is a graph of S parameters (scattering parameters) when the antenna structure 200 operates in the LTE-A low frequency mode, the intermediate frequency mode, and the high frequency mode. The curve S311 is the S11 value when the antenna structure 200 operates at 704-746 MHz. Curve S312 is the S11 value at which the antenna structure 200 operates at 746-787 MHz. Curve S313 is the S11 value at which the antenna structure 200 operates at 791-862 MHz. Curve S314 is the S11 value at which the antenna structure 200 operates at 824-894 MHz. Curve S315 is the S11 value at which the antenna structure 200 operates at 880-960 MHz. Curve S316 is the S11 value at which the antenna structure 200 operates at 1710-2170 MHz. Curve S317 is the S11 value when the antenna structure 200 operates at 2300-2400 MHz. Curve S318 is the S11 value at which the antenna structure 200 operates at 2500-2690 MHz. Obviously, the curves S311-S315 respectively correspond to five different frequency bands, and respectively correspond to five of the plurality of low frequency modes that the first switching circuit 25 can switch.

圖32為所述天線結構200工作於LTE-A低頻模態、中頻模態以及高頻模態時之總輻射效率圖。其中,曲線S321為所述天線結構200工作於704-746MHz時之總輻射效率。曲線S322為所述天線結構200工作於746-787MHz時之總輻射效率。曲線S323為所述天線結構200工作於791-862MHz時之總輻射效率。曲線S324為所述天線結構200工作於824-894MHz時之總輻射效率。曲線S325為所述天線結構200工作於880-960MHz時之總輻射效率。曲線S326為所述天線結構200工作於1710-2170MHz時之總輻射效率。曲線S327為所述天線結構200工作於2300-2400MHz時之總輻射效率。曲線S328為所述天線結構200工作於2500-2690MHz時之總輻射效率。顯然,曲線S321-S325分別對應五個不同頻段,並分別對應第一切換電路25可切換之多個低頻模態之其中五個。32 is a graph showing the total radiation efficiency of the antenna structure 200 when operating in the LTE-A low frequency mode, the intermediate frequency mode, and the high frequency mode. The curve S321 is the total radiation efficiency when the antenna structure 200 operates at 704-746 MHz. Curve S322 is the total radiation efficiency of the antenna structure 200 operating at 746-787 MHz. Curve S323 is the total radiation efficiency of the antenna structure 200 operating at 791-862 MHz. Curve S324 is the total radiation efficiency of the antenna structure 200 operating at 824-894 MHz. Curve S325 is the total radiation efficiency of the antenna structure 200 operating at 880-960 MHz. Curve S326 is the total radiation efficiency of the antenna structure 200 operating at 1710-2170 MHz. Curve S327 is the total radiation efficiency of the antenna structure 200 operating at 2300-2400 MHz. Curve S328 is the total radiation efficiency of the antenna structure 200 operating at 2500-2690 MHz. Obviously, the curves S321-S325 respectively correspond to five different frequency bands, and respectively correspond to five of the plurality of low frequency modes that the first switching circuit 25 can switch.

顯然,從圖31至圖32可知,所述天線結構200可工作於相應之低頻頻段,例如704-960MHz頻段。另外,所述天線結構200還可工作於中頻段(1710-2170MHz頻段)以及高頻段(即2300-2400MHz、2500-2690MHz頻段),即涵蓋至低、中、高頻,頻率範圍較廣,且當所述天線結構200工作於上述頻段時,其工作頻率均可滿足天線工作設計要求,並具有較佳之輻射效率。Obviously, as can be seen from FIG. 31 to FIG. 32, the antenna structure 200 can operate in a corresponding low frequency band, such as the 704-960 MHz band. In addition, the antenna structure 200 can also work in the middle frequency band (1710-2170MHz frequency band) and the high frequency band (ie, 2300-2400MHz, 2500-2690MHz frequency band), that is, cover to low, medium and high frequency, and the frequency range is wide, and When the antenna structure 200 operates in the above frequency band, its operating frequency can meet the antenna working design requirements and has better radiation efficiency.

如前面各實施例所述,所述天線結構200藉由設置所述開槽220、第一斷點221以及第二斷點222,以將所述前框211劃分為第一部分F1及第二部分F2。所述天線結構200還設置有第一饋入源22,以將所述第一部分F1進一步劃分為第一分支H1及第二分支H2,進而使得所述第一饋入源22之電流可分別饋入所述第一分支H1及第二分支H2。如此,所述第一分支H1可激發第一模態以產生低頻頻段之輻射訊號,所述第二分支H2可激發第二模態以產生中頻頻段之輻射訊號。另外,所述第一分支H1可搭配所述諧振電路255,進而額外激發出第三模態以產生第三頻段之輻射訊號。再者,所述天線結構200還設置有輻射體26及所述第二饋入源27,如此可使得所述輻射體26激發出第四模態以產生第四頻段之輻射訊號。因此無線通訊裝置300可使用長期演進技術升級版(LTE-Advanced)之載波聚合(CA,Carrier Aggregation)技術與所述輻射體26、第一分支H1及第二分支H2其中至少兩者同時於多個不同頻段接收或發送無線訊號以增加傳輸頻寬。As described in the foregoing embodiments, the antenna structure 200 divides the front frame 211 into a first portion F1 and a second portion by providing the slot 220, the first break point 221, and the second break point 222. F2. The antenna structure 200 is further provided with a first feed source 22 to further divide the first portion F1 into a first branch H1 and a second branch H2, so that the current of the first feed source 22 can be separately fed. The first branch H1 and the second branch H2 are entered. As such, the first branch H1 can excite the first mode to generate a radiation signal in the low frequency band, and the second branch H2 can excite the second mode to generate a radiation signal in the intermediate frequency band. In addition, the first branch H1 can be matched with the resonant circuit 255 to additionally excite the third mode to generate a radiation signal of the third frequency band. Furthermore, the antenna structure 200 is further provided with a radiator 26 and the second feed source 27, such that the radiator 26 excites a fourth mode to generate a radiation signal of the fourth frequency band. Therefore, the wireless communication device 300 can use the Carrier Aggregation (CA) technology of the LTE-Advanced and the at least two of the radiator 26, the first branch H1, and the second branch H2 at the same time. Different frequency bands receive or transmit wireless signals to increase the transmission bandwidth.

另外,該天線結構200藉由設置所述殼體21,且所述殼體21上之第一開孔218、第二開孔219、開槽219、第一斷點221及第二斷點222均設置於所述前框211及邊框213上,並未設置於所述背板212上,使得所述背板212構成全金屬結構,即所述背板212上並沒有絕緣之開槽、斷線或斷點,使得所述背板212可避免由於開槽、斷線或斷點之設置而影響背板212之完整性與美觀性。In addition, the antenna structure 200 is provided with the housing 21, and the first opening 218, the second opening 219, the slot 219, the first breaking point 221 and the second breaking point 222 on the housing 21. The backplanes 212 are not disposed on the backplane 212, so that the backplanes 212 form an all-metal structure, that is, the backplanes 212 are not insulated and slotted. The line or breakpoint allows the backing plate 212 to avoid affecting the integrity and aesthetics of the backing plate 212 due to the provision of slots, breaks, or breakpoints.

實施例3、4Example 3, 4

請一併參閱圖33,為本發明第三較佳實施例提供之天線結構200a。所述天線結構200a包括殼體21、第一饋入源31、匹配電路23、匹配電路32、第一切換電路25、輻射體26、第二饋入源27、第二接地部28及第二切換電路29。所述殼體21包括前框211、背板212及邊框213。所述邊框213至少包括末端部215、第一側部216以及第二側部217。所述邊框213上還開設有開槽220。所述前框211上開設有第一斷點221及第二斷點322。Please refer to FIG. 33, which is an antenna structure 200a according to a third preferred embodiment of the present invention. The antenna structure 200a includes a housing 21, a first feed source 31, a matching circuit 23, a matching circuit 32, a first switching circuit 25, a radiator 26, a second feed source 27, a second ground portion 28, and a second Switching circuit 29. The housing 21 includes a front frame 211, a back plate 212, and a frame 213. The frame 213 includes at least a tip end portion 215, a first side portion 216, and a second side portion 217. The frame 213 is further provided with a slot 220. A first break point 221 and a second break point 322 are defined in the front frame 211 .

可理解,所述天線結構200a與天線結構200之區別在於,所述天線結構200a中並未設置第一接地部24,所述天線結構200a僅包括一個接地部,即第二接地部28。It can be understood that the antenna structure 200a is different from the antenna structure 200 in that the first ground portion 24 is not disposed in the antenna structure 200a, and the antenna structure 200a includes only one ground portion, that is, the second ground portion 28.

可理解,於本實施例中,所述天線結構200a中第二斷點322之位置與天線結構200中第二斷點222之位置不同。具體所述第一斷點221開設於所述前框211上,且與所述開槽220佈設於所述第一側部216之第一末端D1連通。所述第二斷點322開設於所述前框211上。所述第二斷點322並非設置於所述前框211與所述開槽220之第二末端D2相對應之地方,而是設置於所述第一末端D1與第二末端D2之間,且鄰近所述第二側部217設置。如此,所述開槽220及第一斷點221共同自所述殼體21劃分出第一部分F1及第二部分F2。其中,所述第一斷點221一側之所述前框211直至其延伸至與所述開槽220之第二末端D2相對應之部分共同形成所述第一部分F1,所述殼體21剩餘之部分則構成所述第二部分F2。所述第二部分F2接地。It can be understood that, in this embodiment, the position of the second break point 322 in the antenna structure 200a is different from the position of the second break point 222 in the antenna structure 200. Specifically, the first break point 221 is formed on the front frame 211 and communicates with the first end D1 of the first side portion 216 . The second break point 322 is opened on the front frame 211. The second break point 322 is not disposed at a position corresponding to the second end D2 of the slot 220, but is disposed between the first end D1 and the second end D2, and Adjacent to the second side portion 217. In this manner, the slot 220 and the first break point 221 collectively divide the first portion F1 and the second portion F2 from the housing 21 . The front frame 211 on the side of the first break point 221 until it extends to a portion corresponding to the second end D2 of the slot 220 to form the first portion F1, the housing 21 remaining The portion constitutes the second portion F2. The second portion F2 is grounded.

另外,所述第二斷點322進一步將所述第一部分F1劃分為兩部分,即第一分支K1及第二分支K2。其中,所述第一斷點221與第二斷點322之間之所述前框211構成所述第一分支K1。所述第二斷點322一側之前框211直至其延伸至與所述開槽220之第二末端D2相對應之部分所述第二分支K2。所述第一分支K1之長度大於所述第二分支K2之長度。In addition, the second break point 322 further divides the first portion F1 into two parts, that is, a first branch K1 and a second branch K2. The front frame 211 between the first break point 221 and the second break point 322 constitutes the first branch K1. The second break point 322 is on the side of the front frame 211 until it extends to a portion of the second branch K2 corresponding to the second end D2 of the slot 220. The length of the first branch K1 is greater than the length of the second branch K2.

可理解,於本實施例中,所述第一饋入源31與其他元件之連接關係亦不同於與天線結構200中之第一饋入源22。具體所述第一饋入源31之一端藉由匹配電路23電連接至所述第一分支K1鄰近所述第二斷點322之位置,所述第一饋入源31之另一端則藉由另一匹配電路32電連接至所述第二分支K2鄰近所述第二末端D2之位置,用以分別為所述第一分支K1及第二分支K2饋入電流。It can be understood that, in this embodiment, the connection relationship between the first feed source 31 and other components is also different from the first feed source 22 in the antenna structure 200. Specifically, one end of the first feed source 31 is electrically connected to a position of the first branch K1 adjacent to the second break point 322 by a matching circuit 23, and the other end of the first feed source 31 is Another matching circuit 32 is electrically connected to a position of the second branch K2 adjacent to the second end D2 for respectively feeding current to the first branch K1 and the second branch K2.

請一併參閱圖34,當電流自所述第一饋入源31進入後,電流將流入所述第一部分F1之第一分支K1,並流向所述第一斷點221(參路徑J1),進而使得所述第一分支K1激發一第一模態以產生第一頻段之輻射訊號。本實施例中,所述第一模態為一低頻模態。所述第一頻段為704-960MHz頻段。另外,當電流自所述第一饋入源31進入後,電流還將流入所述第二分支K2,並流向所述第二斷點322(參路徑J2),進而使得所述第二分支K2激發一第二模態以產生第二頻段之輻射訊號。本實施例中,所述第二模態為一中頻模態。所述第二頻段之頻率高於所述第一頻段之頻率。所述第二頻段為1710-1990MHz頻段。另外,流過所述第一分支K1中之電流流向所述第一切換電路25中之諧振電路255,並最終流向所述第一斷點221(參路徑J3),以使得所述第一分支K1搭配所述諧振電路255,進而使得所述第一分支K1額外激發出所述第三模態以產生第三頻段之輻射訊號。所述第三頻段為2110-2170MHz頻段。當電流自所述第二饋入源27饋入後,將流經所述輻射體26(參路徑J4),進而激發出所述第四模態以產生第四頻段之輻射訊號。所述第四頻段為2300-2690MHz頻段。所述天線結構200a工作於LTE-A低、中、高頻時之S參數(散射參數)與總輻射效率均與所述天線結構200相同,如圖31與圖32所示。Referring to FIG. 34 together, when current enters from the first feed source 31, current will flow into the first branch K1 of the first portion F1 and flow to the first break point 221 (refer to path J1). The first branch K1 is further excited to generate a first mode to generate a radiation signal of the first frequency band. In this embodiment, the first mode is a low frequency mode. The first frequency band is a frequency band of 704-960 MHz. In addition, when a current enters from the first feed source 31, current will also flow into the second branch K2 and flow to the second break point 322 (refer to path J2), thereby causing the second branch K2. A second mode is excited to generate a radiation signal of the second frequency band. In this embodiment, the second mode is an intermediate frequency mode. The frequency of the second frequency band is higher than the frequency of the first frequency band. The second frequency band is the 1710-1990 MHz frequency band. In addition, the current flowing in the first branch K1 flows to the resonant circuit 255 in the first switching circuit 25, and finally flows to the first break point 221 (refer to the path J3), so that the first branch The first circuit K1 additionally excites the third mode to generate a radiation signal of the third frequency band. The third frequency band is a frequency band of 2110-2170 MHz. When the current is fed from the second feed source 27, it will flow through the radiator 26 (refer to path J4), thereby exciting the fourth mode to generate a radiation signal of the fourth frequency band. The fourth frequency band is a frequency band of 2300-2690 MHz. The S-parameter (scattering parameter) and the total radiation efficiency of the antenna structure 200a operating at low, medium, and high frequencies of LTE-A are the same as those of the antenna structure 200, as shown in FIGS. 31 and 32.

請一併參閱圖35,為本發明第四較佳實施例提供之天線結構200b。所述天線結構200b包括殼體21、第一饋入源33、匹配電路23、第一切換電路25、輻射體26、第二饋入源27、第二接地部28及第二切換電路29。所述殼體21包括前框211、背板212及邊框213。所述邊框213至少包括末端部215、第一側部216以及第二側部217。所述邊框213上還開設有開槽220。所述前框211上開設有第一斷點221及第二斷點322。Please refer to FIG. 35, which is an antenna structure 200b according to a fourth preferred embodiment of the present invention. The antenna structure 200b includes a housing 21, a first feed source 33, a matching circuit 23, a first switching circuit 25, a radiator 26, a second feed source 27, a second ground portion 28, and a second switching circuit 29. The housing 21 includes a front frame 211, a back plate 212, and a frame 213. The frame 213 includes at least a tip end portion 215, a first side portion 216, and a second side portion 217. The frame 213 is further provided with a slot 220. A first break point 221 and a second break point 322 are defined in the front frame 211 .

可理解,所述天線結構200b與天線結構200a之區別在於,所述第一饋入源33與其他元件之連接關係亦不同於與天線結構200a中之第一饋入源31。具體所述第一饋入源33之一端藉由匹配電路23電連接至所述第一分支K1鄰近所述第二斷點322之位置,所述第一饋入源33之另一端則電連接至所述背板212,即接地。It can be understood that the antenna structure 200b is different from the antenna structure 200a in that the connection relationship between the first feed source 33 and other components is also different from that of the first feed source 31 in the antenna structure 200a. Specifically, one end of the first feed source 33 is electrically connected to a position of the first branch K1 adjacent to the second break point 322 by a matching circuit 23, and the other end of the first feed source 33 is electrically connected. To the backing plate 212, that is, grounded.

請一併參閱圖36,當電流自所述第一饋入源33進入後,電流將流入所述第一部分F1之第一分支K1,並流向所述第一斷點221(參路徑Q1),進而使得所述第一分支K1激發第一模態以產生第一頻段之輻射訊號。另外,當電流自所述第一饋入源33進入所述第一分支K1後,電流還將藉由所述第二斷點322耦合至所述第二分支K2,並流向所述背板212(參路徑Q2),進而使得所述第二分支K2激發第二模態以產生第二頻段之輻射訊號。另外,流過所述第一分支K1中之電流流向所述第一切換電路25中之諧振電路255,並最終流向所述第一斷點221(參路徑Q3),以使得所述第一分支K1搭配所述諧振電路255,進而使得所述第一分支K1額外激發出所述第三模態以產生第三頻段之輻射訊號。當電流自所述第二饋入源27饋入後,將流經所述輻射體26(參路徑Q4),進而激發出所述第四模態以產生第四頻段之輻射訊號。所述路徑Q1-Q4所對應之第一模態至第四模態與第一頻段至第四頻段分別與圖34其中之路徑J1-J4相同。所述天線結構200b工作於LTE-A低、中、高頻時之S參數(散射參數)與總輻射效率均與所述天線結構200相同,如圖31與圖32所示。Referring to FIG. 36 together, when current enters from the first feed source 33, current will flow into the first branch K1 of the first portion F1 and flow to the first break point 221 (refer to the path Q1). The first branch K1 is further caused to excite the first mode to generate a radiation signal of the first frequency band. In addition, when a current enters the first branch K1 from the first feed source 33, current will also be coupled to the second branch K2 by the second break point 322 and flow to the back plate 212. (Refer to path Q2), which in turn causes the second branch K2 to excite the second mode to generate a radiation signal of the second frequency band. In addition, a current flowing in the first branch K1 flows to the resonant circuit 255 in the first switching circuit 25, and finally flows to the first break point 221 (refer to the path Q3), so that the first branch The first circuit K1 additionally excites the third mode to generate a radiation signal of the third frequency band. When the current is fed from the second feed source 27, it will flow through the radiator 26 (refer to path Q4), thereby exciting the fourth mode to generate a radiation signal of the fourth frequency band. The first to fourth modes corresponding to the paths Q1-Q4 and the first to fourth frequency bands are respectively the same as the paths J1-J4 in FIG. The S-parameter (scattering parameter) and the total radiation efficiency of the antenna structure 200b operating at low, medium and high frequencies of LTE-A are the same as those of the antenna structure 200, as shown in FIGS. 31 and 32.

本發明第一較佳實施例之天線結構100、本發明第二較佳實施例之天線結構200、本發明第三較佳實施例之天線結構200a及本發明第四較佳實施例之天線結構200b可應用於同一個無線通訊裝置。例如將天線結構100設置於該無線通訊裝置之上端作為副天線,並將天線結構200、200a或200b設置於該無線通訊裝置之下端作為主天線。當該無線通訊裝置發送無線訊號時,該無線通訊裝置使用所述主天線發送無線訊號。當該無線通訊裝置接收無線訊號時,該無線通訊裝置使用所述主天線與所述副天線一起接收無線訊號。The antenna structure 100 of the first preferred embodiment of the present invention, the antenna structure 200 of the second preferred embodiment of the present invention, the antenna structure 200a of the third preferred embodiment of the present invention, and the antenna structure of the fourth preferred embodiment of the present invention 200b can be applied to the same wireless communication device. For example, the antenna structure 100 is disposed at the upper end of the wireless communication device as a secondary antenna, and the antenna structure 200, 200a or 200b is disposed at a lower end of the wireless communication device as a primary antenna. When the wireless communication device transmits a wireless signal, the wireless communication device transmits the wireless signal using the primary antenna. When the wireless communication device receives the wireless signal, the wireless communication device uses the primary antenna to receive the wireless signal together with the secondary antenna.

以上所述,僅為本發明的較佳實施例,並非是對本發明作任何形式上的限定。另外,本領域技術人員還可在本發明精神內做其它變化,當然,這些依據本發明精神所做的變化,都應包含在本發明所要求保護的範圍之內。The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way. In addition, those skilled in the art can make other changes in the spirit of the present invention. Of course, the changes made in accordance with the spirit of the present invention should be included in the scope of the present invention.

100、300、400、500‧‧‧天線結構
11、51‧‧‧殼體
111、511‧‧‧前框
110、512‧‧‧背板
112、513‧‧‧邊框
113、514‧‧‧容置空間
114、515‧‧‧末端部
115、516‧‧‧第一側部
116、517‧‧‧第二側部
518‧‧‧第一開孔
519‧‧‧第二開孔
117、520‧‧‧開槽
118、521‧‧‧第一斷點
119、522‧‧‧第二斷點
120‧‧‧縫隙
F1‧‧‧天線部
E2‧‧‧接地區
T1、D1‧‧‧第一端
T2、D2‧‧‧第二端
A1‧‧‧第一部分
A2‧‧‧第二部分
E1‧‧‧第一輻射部
E2‧‧‧第二輻射部
12‧‧‧第一饋入部
S1、S2‧‧‧第二饋入部
13、33、43‧‧‧輻射體
132、B1‧‧‧第一分支
133、B2‧‧‧第二分支
134‧‧‧第一連接段
135‧‧‧第二連接段
136‧‧‧第一延伸段
137‧‧‧第二延伸段
138‧‧‧第三延伸段
53‧‧‧饋入部
55‧‧‧共振部
139、551‧‧‧第一共振段
140、553‧‧‧第二共振段
555‧‧‧第三共振段
557‧‧‧第四共振段
56‧‧‧接地部
G1‧‧‧第一接地部
G2‧‧‧第二接地部
15、57‧‧‧第一切換電路
151、571‧‧‧第一切換單元
153、573‧‧‧第一切換元件
17、58‧‧‧第二切換電路
171、581‧‧‧第二切換單元
173、583‧‧‧第二切換元件
131、59‧‧‧連接部
200、600‧‧‧無線通訊裝置
601‧‧‧顯示單元
201、301、602‧‧‧第一電子元件
202、302、603‧‧‧第二電子元件
203、303‧‧‧第三電子元件
204、304‧‧‧第四電子元件
305‧‧‧第五電子元件
604‧‧‧相機鏡頭
605‧‧‧閃光燈
606、607‧‧‧開孔
331‧‧‧第一輻射臂
332‧‧‧第二輻射臂
333‧‧‧第三輻射臂
334‧‧‧第四輻射臂
335‧‧‧第五輻射臂
336‧‧‧第六輻射臂
431‧‧‧第一輻射段
432‧‧‧第二輻射段
433‧‧‧第三輻射段
434‧‧‧第四輻射段
435‧‧‧第五輻射段
451‧‧‧雙工器
453‧‧‧訊號提取器
455‧‧‧三工器
100, 300, 400, 500‧‧‧ antenna structure
11, 51‧‧‧ shell
111, 511‧‧‧ front box
110, 512‧‧‧ Backplane
112, 513‧‧‧ border
113, 514‧‧‧ accommodating space
114, 515‧‧‧ end
115, 516‧‧‧ first side
116, 517‧‧‧ second side
518‧‧‧First opening
519‧‧‧Second opening
117, 520‧‧‧ slotting
118, 521‧‧‧ first breakpoint
119, 522‧‧‧ second breakpoint
120‧‧‧ gap
F1‧‧‧Antenna Department
E2‧‧‧Contact area
T1, D1‧‧‧ first end
T2, D2‧‧‧ second end
Part A1‧‧‧
A2‧‧‧ Part II
E1‧‧‧First Radiation Department
E2‧‧‧Second Radiation Department
12‧‧‧First Feeding Department
S1, S2‧‧‧Second Feeding Department
13, 33, 43‧‧‧ radiators
132, the first branch of B1‧‧
133. The second branch of B2‧‧
134‧‧‧First connection segment
135‧‧‧Second connection
136‧‧‧First extension
137‧‧‧Second extension
138‧‧‧ third extension
53‧‧‧Feeding Department
55‧‧‧Resonance
139, 551‧‧‧ first resonance
140, 553‧‧‧second resonance
555‧‧‧3rd resonance section
557‧‧‧fourth resonance section
56‧‧‧ Grounding Department
G1‧‧‧First grounding
G2‧‧‧Second grounding
15, 57‧‧‧ first switching circuit
151, 571‧‧‧ first switching unit
153, 573‧‧‧ first switching element
17, 58‧‧‧ second switching circuit
171, 581‧‧‧ second switching unit
173, 583‧‧‧ second switching element
131, 59‧‧‧ Connections
200, 600‧‧‧ wireless communication device
601‧‧‧ display unit
201, 301, 602‧‧‧ first electronic components
202, 302, 603‧‧‧ second electronic components
203, 303‧‧‧ third electronic components
204, 304‧‧‧ fourth electronic components
305‧‧‧ fifth electronic component
604‧‧‧ camera lens
605‧‧‧flash
606, 607‧‧‧ openings
331‧‧‧First Radiation Arm
332‧‧‧second radiation arm
333‧‧‧ Third Radiation Arm
334‧‧‧fourth radial arm
335‧‧‧ fifth radiation arm
336‧‧‧ sixth radiation arm
431‧‧‧First radiant section
432‧‧‧second radiant section
433‧‧‧third radiant section
434‧‧‧fourth radiant section
435‧‧‧ fifth radiant section
451‧‧‧Duplexer
453‧‧‧Signal Extractor
455‧‧‧Three-worker

圖1為本發明第一較佳實施例之天線結構應用至無線通訊裝置之示意圖。 圖2為圖1所示無線通訊裝置之組裝示意圖。 圖3為圖1所示天線結構之電路圖。 圖4為圖2所示無線通訊裝置另一角度下之組裝示意圖。 圖5為圖1所示天線結構中切換電路之電路圖。 圖6為圖5所示切換電路設置有諧振電路之電路圖。 圖7為圖5所示切換電路設置有諧振電路之另一電路圖。 圖8為當圖6所示切換電路設置有諧振電路時產生窄頻模態之工作原理圖。 圖9為當圖7所示切換電路設置有諧振電路時產生窄頻模態之工作原理圖。 圖10為圖6所示諧振電路之另一電路圖。 圖11為圖7所示諧振電路之另一電路圖。 圖12為當圖10-11所示切換電路設置有諧振電路時產生窄頻模態之工作原理圖。 圖13為圖1所示天線結構工作之電流走向示意圖。 圖14為圖1所示天線結構工作於低頻模態、GPS模態以及中頻模態時之S參數(散射參數)曲線圖。 圖15為圖1所示天線結構工作於低頻模態、GPS模態以及中頻模態時之總輻射效率圖。 圖16為圖1所示天線結構工作於高頻模態及WIFI 2.4G模態時之S參數(散射參數)曲線圖。 圖17為圖1所示天線結構工作於高頻模態及WIFI 2.4G模態時之總輻射效率圖。 圖18為本發明第二較佳實施例之天線結構應用至無線通訊裝置之示意圖。 圖19為圖18所示無線通訊裝置之組裝示意圖。 圖20為圖18所示天線結構之電路圖。 圖21為圖19所示無線通訊裝置另一角度下之組裝示意圖。 圖22為圖18所示天線結構中第一切換電路之電路圖。 圖23為圖22所示第一切換電路設置有諧振電路之電路圖。 圖24為圖22所示第一切換電路設置有諧振電路之另一電路圖。 圖25為當圖23所示第一切換電路設置有諧振電路時產生窄頻模態之工作原理圖。 圖26為當圖24所示第一切換電路設置有諧振電路時產生窄頻模態之工作原理圖。 圖27為圖23所示諧振電路之另一電路圖。 圖28為圖24所示諧振電路之另一電路圖。 圖29為當圖27-28所示第一切換電路設置有諧振電路時產生窄頻模態之工作原理圖。 圖30為圖18所示天線結構工作之電流走向示意圖。 圖31為圖18所示天線結構工作於低、中、高頻時之S參數(散射參數)曲線圖。 圖32為圖18所示天線結構工作於低、中、高頻時之總輻射效率圖。 圖33為本發明第三較佳實施例之天線結構應用至無線通訊裝置之示意圖。 圖34為圖33所示天線結構工作之電流走向示意圖。 圖35為本發明第四較佳實施例之天線結構應用至無線通訊裝置之示意圖。 圖36為圖35所示天線結構工作之電流走向示意圖。1 is a schematic diagram of an antenna structure applied to a wireless communication device according to a first preferred embodiment of the present invention. 2 is a schematic view showing the assembly of the wireless communication device shown in FIG. 1. 3 is a circuit diagram of the antenna structure shown in FIG. 1. 4 is a schematic view showing the assembly of the wireless communication device shown in FIG. 2 from another angle. FIG. 5 is a circuit diagram of a switching circuit in the antenna structure shown in FIG. 1. FIG. FIG. 6 is a circuit diagram of the switching circuit of FIG. 5 provided with a resonant circuit. FIG. 7 is another circuit diagram of the switching circuit of FIG. 5 provided with a resonant circuit. FIG. 8 is a schematic diagram showing the operation of generating a narrow frequency mode when the switching circuit shown in FIG. 6 is provided with a resonant circuit. FIG. 9 is a schematic diagram showing the operation of generating a narrow-band mode when the switching circuit shown in FIG. 7 is provided with a resonant circuit. Figure 10 is another circuit diagram of the resonant circuit shown in Figure 6. Figure 11 is another circuit diagram of the resonant circuit shown in Figure 7. FIG. 12 is a schematic diagram showing the operation of generating a narrow frequency mode when the switching circuit shown in FIGS. 10-11 is provided with a resonant circuit. FIG. 13 is a schematic diagram showing the current flow of the antenna structure shown in FIG. 1. 14 is a graph of S-parameters (scattering parameters) of the antenna structure of FIG. 1 operating in a low frequency mode, a GPS mode, and an intermediate frequency mode. 15 is a graph showing the total radiation efficiency of the antenna structure shown in FIG. 1 when operating in a low frequency mode, a GPS mode, and an intermediate frequency mode. FIG. 16 is a graph of S-parameters (scattering parameters) of the antenna structure shown in FIG. 1 when operating in a high frequency mode and a WIFI 2.4G mode. 17 is a graph showing the total radiation efficiency of the antenna structure shown in FIG. 1 when operating in a high frequency mode and a WIFI 2.4G mode. FIG. 18 is a schematic diagram of an antenna structure applied to a wireless communication device according to a second preferred embodiment of the present invention. 19 is a schematic view showing the assembly of the wireless communication device shown in FIG. 18. Figure 20 is a circuit diagram of the antenna structure shown in Figure 18. 21 is a schematic view showing the assembly of the wireless communication device shown in FIG. 19 at another angle. Figure 22 is a circuit diagram of the first switching circuit in the antenna structure shown in Figure 18. Figure 23 is a circuit diagram showing the first switching circuit shown in Figure 22 with a resonant circuit. FIG. 24 is another circuit diagram of the first switching circuit shown in FIG. 22 provided with a resonant circuit. Figure 25 is a diagram showing the operation of generating a narrow frequency mode when the first switching circuit shown in Figure 23 is provided with a resonant circuit. Fig. 26 is a view showing the operation of generating a narrow frequency mode when the first switching circuit shown in Fig. 24 is provided with a resonance circuit. Figure 27 is another circuit diagram of the resonant circuit shown in Figure 23. Figure 28 is another circuit diagram of the resonant circuit shown in Figure 24. Figure 29 is a diagram showing the operation of generating a narrow frequency mode when the first switching circuit shown in Figures 27-28 is provided with a resonant circuit. Figure 30 is a schematic diagram showing the current flow of the antenna structure shown in Figure 18. Fig. 31 is a graph showing the S parameter (scattering parameter) of the antenna structure shown in Fig. 18 operating at low, medium and high frequencies. Figure 32 is a graph showing the total radiation efficiency of the antenna structure of Figure 18 operating at low, medium and high frequencies. 33 is a schematic diagram of an antenna structure applied to a wireless communication device according to a third preferred embodiment of the present invention. Figure 34 is a schematic diagram showing the current flow of the antenna structure shown in Figure 33. 35 is a schematic diagram of an antenna structure applied to a wireless communication device according to a fourth preferred embodiment of the present invention. Figure 36 is a schematic diagram showing the current flow of the antenna structure shown in Figure 35.

no

200a‧‧‧天線結構 200a‧‧‧Antenna structure

21‧‧‧殼體 21‧‧‧ housing

211‧‧‧前框 211‧‧‧ front box

212‧‧‧背板 212‧‧‧ Backplane

213‧‧‧邊框 213‧‧‧Border

214‧‧‧容置空間 214‧‧‧ accommodating space

215‧‧‧末端部 215‧‧‧End

216‧‧‧第一側部 216‧‧‧ first side

217‧‧‧第二側部 217‧‧‧ second side

218‧‧‧第一開孔 218‧‧‧ first opening

219‧‧‧第二開孔 219‧‧‧Second opening

220‧‧‧開槽 220‧‧‧ slotting

221‧‧‧第一斷點 221‧‧‧ first breakpoint

322‧‧‧第二斷點 322‧‧‧second breakpoint

F1‧‧‧第一部分 F1‧‧‧Part 1

F2‧‧‧第二部分 F2‧‧‧Part II

D1‧‧‧第一末端 D1‧‧‧ first end

D2‧‧‧第二末端 D2‧‧‧ second end

K1‧‧‧第一分支 First branch of K1‧‧

K2‧‧‧第二分支 K2‧‧‧ second branch

31‧‧‧第一饋入源 31‧‧‧First feed source

23、32‧‧‧匹配電路 23, 32‧‧‧ Matching circuit

25‧‧‧第一切換電路 25‧‧‧First switching circuit

26‧‧‧輻射體 26‧‧‧ radiator

27‧‧‧第二饋入源 27‧‧‧second feed source

28‧‧‧第二接地部 28‧‧‧Second grounding

29‧‧‧第二切換電路 29‧‧‧Second switching circuit

300‧‧‧無線通訊裝置 300‧‧‧Wireless communication device

301‧‧‧顯示單元 301‧‧‧Display unit

302‧‧‧第一電子元件 302‧‧‧First electronic component

303‧‧‧第二電子元件 303‧‧‧Second electronic components

Claims (17)

一種天線結構,包括殼體、第一饋入源以及第一切換電路,所述殼體包括前框、背板以及邊框,所述邊框夾設於所述前框與所述背板之間,所述邊框上開設有開槽,所述前框上開設有第一斷點及第二斷點,所述第一斷點與所述開槽之第一末端連通並延伸至隔斷所述前框,所述第二斷點設置於所述第一斷點與所述開槽之第二末端之間並延伸至隔斷所述前框,所述開槽、所述第一斷點及所述第二斷點共同自所述殼體劃分出第一分支及第二分支,所述第一斷點與所述第二斷點之間之所述前框構成所述第一分支,所述第二斷點與所述第二末端之間之所述前框構成所述第二分支,所述第二分支於所述第二末端之位置接地,所述第一饋入源電連接至所述第一分支,所述第一切換電路之一端電連接至所述第一分支,另一端接地。An antenna structure includes a housing, a first feeding source, and a first switching circuit, the housing includes a front frame, a backboard, and a frame, and the frame is sandwiched between the front frame and the backboard. a slot is formed in the frame, the first frame is open with a first break point and a second break point, and the first break point is connected to the first end of the slot and extends to block the front frame The second break point is disposed between the first break point and the second end of the slot and extends to block the front frame, the slot, the first break point, and the first The two break points jointly divide the first branch and the second branch from the housing, and the front frame between the first break point and the second break point constitutes the first branch, and the second The front frame between the break point and the second end constitutes the second branch, the second branch is grounded at the position of the second end, and the first feed source is electrically connected to the first A branch, one end of the first switching circuit is electrically connected to the first branch, and the other end is grounded. 如申請專利範圍第1項所述之天線結構,其中所述開槽、所述第一斷點及所述第二斷點內均填充有絕緣材料。The antenna structure of claim 1, wherein the slot, the first breakpoint, and the second breakpoint are filled with an insulating material. 如申請專利範圍第1項所述之天線結構,其中所述第一饋入源之一端電連接至所述第一分支,所述第一饋入源之另一端電連接至所述第二分支,當電流自所述第一饋入源進入後,將流經所述第一分支,並流向所述第一斷點,進而激發出第一模態以產生第一頻段之輻射訊號;當電流自所述第一饋入源進入後,電流還流經所述第二分支,並流向所述第二斷點,進而激發出第二模態以產生第二頻段之輻射訊號,所述第一頻段之頻率低於第二頻段之頻率。The antenna structure of claim 1, wherein one end of the first feed source is electrically connected to the first branch, and the other end of the first feed source is electrically connected to the second branch After the current enters from the first feed source, it will flow through the first branch and flow to the first breakpoint, thereby exciting the first mode to generate a radiation signal of the first frequency band; After entering the first feed source, current also flows through the second branch and flows to the second breakpoint, thereby exciting a second mode to generate a radiation signal of the second frequency band, the first frequency band The frequency is lower than the frequency of the second frequency band. 如申請專利範圍第1項所述之天線結構,其中所述第一饋入源之一端電連接至所述第一分支,所述第一饋入源之另一端接地,當電流自所述第一饋入源進入後,將流經所述第一分支,並流向所述第一斷點,進而激發出第一模態以產生第一頻段之輻射訊號;當電流自所述第一饋入源進入後,電流還藉由所述第二斷點耦合至所述第二分支,並流向所述背板,進而激發出第二模態以產生第二頻段之輻射訊號,所述第二頻段之頻率高於第一頻段之頻率。The antenna structure of claim 1, wherein one end of the first feed source is electrically connected to the first branch, and the other end of the first feed source is grounded, when current is from the After a feed source enters, it will flow through the first branch and flow to the first breakpoint, thereby exciting the first mode to generate a radiation signal of the first frequency band; when the current is fed from the first After the source enters, the current is also coupled to the second branch by the second breakpoint and flows to the backplane, thereby exciting the second mode to generate a second frequency band of the radiation signal, the second frequency band The frequency is higher than the frequency of the first frequency band. 如申請專利範圍第3或4項所述之天線結構,其中所述第一切換電路包括切換單元及至少一切換元件,所述切換單元電連接至所述第一分支,所述切換元件之間相互並聯,且其一端電連接至所述切換單元,另一端連接至所述背板,藉由控制所述切換單元之切換,使得所述切換單元切換至不同之切換元件,進而調整所述第一頻段。The antenna structure of claim 3 or 4, wherein the first switching circuit comprises a switching unit and at least one switching element, the switching unit being electrically connected to the first branch, between the switching elements Parallel to each other, and one end thereof is electrically connected to the switching unit, and the other end is connected to the backplane, and by switching the switching unit, the switching unit is switched to different switching elements, thereby adjusting the One band. 如申請專利範圍第5項所述之天線結構,其中所述第一切換電路還包括諧振電路,所述諧振電路用以使得所述第一分支額外激發出第三模態以產生第三頻段之輻射訊號,所述第三頻段之頻率高於所述第二頻段之頻率。The antenna structure of claim 5, wherein the first switching circuit further comprises a resonant circuit, wherein the resonant circuit is configured to cause the first branch to additionally excite a third mode to generate a third frequency band. The radiation signal, the frequency of the third frequency band is higher than the frequency of the second frequency band. 如申請專利範圍第6項所述之天線結構,其中所述諧振電路之數量為一個,所述諧振電路電連接於所述第一分支及所述背板之間,且與所述切換單元及至少一個切換元件並聯設置。The antenna structure of claim 6, wherein the number of the resonant circuits is one, the resonant circuit is electrically connected between the first branch and the backplane, and the switching unit and At least one switching element is arranged in parallel. 如申請專利範圍第6項所述之天線結構,其中所述諧振電路之數量與所述切換元件之數量一致,每一所述諧振電路分別電連接至所述切換單元及所述背板,並與對應之切換元件並聯設置,當所述第一頻段被調整時,所述諧振電路使所述第三頻段維持不變。The antenna structure of claim 6, wherein the number of the resonant circuits is the same as the number of the switching elements, and each of the resonant circuits is electrically connected to the switching unit and the backplane, respectively. Arranging in parallel with the corresponding switching element, the resonant circuit maintains the third frequency band unchanged when the first frequency band is adjusted. 如申請專利範圍第6項所述之天線結構,其中所述諧振電路之數量與所述切換元件之數量一致,每一所述諧振電路分別電連接至所述切換單元及所述背板,並與對應之切換元件並聯設置,當所述第一頻段被調整時,所述諧振電路對應調整所述第三頻段。The antenna structure of claim 6, wherein the number of the resonant circuits is the same as the number of the switching elements, and each of the resonant circuits is electrically connected to the switching unit and the backplane, respectively. And being disposed in parallel with the corresponding switching element, when the first frequency band is adjusted, the resonant circuit correspondingly adjusts the third frequency band. 如申請專利範圍第6項所述之天線結構,其中所述天線結構還包括輻射體、第二饋入源以及接地部,所述邊框至少包括末端部、第一側部以及第二側部,所述第一側部與所述第二側部分別連接所述末端部之兩端,所述輻射體與所述末端部平行設置,且鄰近所述第一側部設置,所述第二饋入源及所述接地部均電連接至所述輻射體,當電流自所述第二饋入源進入後,將流經所述輻射體,進而激發出第四模態以產生第四頻段之輻射訊號,所述第四頻段之頻率高於第三頻段之頻率。The antenna structure of claim 6, wherein the antenna structure further includes a radiator, a second feed source, and a ground portion, the frame including at least a tip portion, a first side portion, and a second side portion, The first side portion and the second side portion are respectively connected to two ends of the end portion, the radiator is disposed in parallel with the end portion, and is disposed adjacent to the first side portion, and the second feed The source and the grounding portion are both electrically connected to the radiator, and when a current enters from the second feeding source, it will flow through the radiator, thereby exciting a fourth mode to generate a fourth frequency band. The radiation signal, the frequency of the fourth frequency band is higher than the frequency of the third frequency band. 如申請專利範圍第10項所述之天線結構,其中所述天線結構還包括第二切換電路,所述第二切換電路之一端電連接至所述輻射體,另一端電連接至所述背板,用以調整所述第四頻段。The antenna structure of claim 10, wherein the antenna structure further comprises a second switching circuit, one end of the second switching circuit is electrically connected to the radiator, and the other end is electrically connected to the backplane For adjusting the fourth frequency band. 如申請專利範圍第10項所述之天線結構,其中無線通訊裝置使用載波聚合技術並使用所述第一分支、第二分支及所述輻射體其中至少兩者同時於多個不同頻段接收或發送無線訊號。The antenna structure of claim 10, wherein the wireless communication device uses a carrier aggregation technique and uses the first branch, the second branch, and the radiator to receive or transmit simultaneously in a plurality of different frequency bands. Wireless signal. 如申請專利範圍第1項所述之天線結構,其中所述背板為一體成型之單一金屬片,所述背板與邊框直接連接,所述背板與邊框之間沒有空隙,所述背板上並無設置任何用於分割所述背板之絕緣之開槽、斷線或斷點。The antenna structure of claim 1, wherein the backboard is a single metal piece integrally formed, the backboard is directly connected to the frame, and there is no gap between the backboard and the frame, the backboard There are no slots, broken wires or breakpoints for separating the insulation of the backplane. 一種無線通訊裝置,包括如申請專利範圍第1-9、13項中任一項所述之天線結構。A wireless communication device comprising the antenna structure according to any one of claims 1-9 and 13. 如申請專利範圍第14項所述之無線通訊裝置,其中所述無線通訊裝置還包括顯示單元,所述前框、背板以及邊框構成所述無線通訊裝置之外殼,所述前框設置有開口用於容置所述顯示單元,所述顯示單元具有顯示平面,該顯示平面裸露於該開口,且該顯示平面與所述背板平行設置。The wireless communication device of claim 14, wherein the wireless communication device further comprises a display unit, the front frame, the back panel and the frame constitute an outer casing of the wireless communication device, and the front frame is provided with an opening The display unit has a display plane, the display plane is exposed to the opening, and the display plane is disposed in parallel with the backboard. 如申請專利範圍第14項所述之無線通訊裝置,其中所述無線通訊裝置還包括耳機介面模組,所述天線結構還包括輻射體、第二饋入源、接地部以及第二切換電路,所述邊框至少包括末端部、第一側部以及第二側部,所述第一側部與所述第二側部分別連接所述末端部之兩端,所述輻射體與所述末端部平行設置,且跨越所述耳機介面模組之上方並與所述耳機介面模組間隔設置,所述第二饋入源設置於所述第一側部與所述耳機介面模組之間,且電連接至所述輻射體,所述接地部設置於所述耳機介面模組靠近所述第一側部之一側,且電連接至所述輻射體,所述第二切換電路設置於所述耳機介面模組靠近所述第二側部之一側,所述第二切換電路之一端電連接至所述輻射體,另一端電連接至所述背板,用以調整所述天線結構之頻段。The wireless communication device of claim 14, wherein the wireless communication device further comprises a headphone interface module, the antenna structure further comprising a radiator, a second feed source, a ground portion, and a second switching circuit. The frame includes at least a distal end portion, a first side portion, and a second side portion, the first side portion and the second side portion respectively connecting the two ends of the end portion, the radiator and the end portion The second feed source is disposed between the first side portion and the earphone interface module, and is disposed in parallel with the headphone interface module and spaced apart from the earphone interface module, and Electrically connected to the radiator, the grounding portion is disposed on a side of the earphone interface module adjacent to the first side portion, and is electrically connected to the radiator, and the second switching circuit is disposed on the The earphone interface module is adjacent to one side of the second side portion, one end of the second switching circuit is electrically connected to the radiator, and the other end is electrically connected to the backboard for adjusting a frequency band of the antenna structure . 如申請專利範圍第16項所述之無線通訊裝置,其中無線通訊裝置使用載波聚合技術並使用所述第一分支、第二分支及所述輻射體其中至少兩者同時於多個不同頻段接收或發送無線訊號。The wireless communication device of claim 16, wherein the wireless communication device uses carrier aggregation technology and uses at least two of the first branch, the second branch, and the radiator to simultaneously receive in a plurality of different frequency bands or Send a wireless signal.
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